Abstract: The MOS transistor of the present invention is manufactured by a conventional complementary MOS transistor technology. In the manufacturing method of the MOS transistor having nanometer dimensions, a gate having dimensions at a nanometer scale can be formed through control of the width of spacers instead of with a specific lithography technology. The doped spacers are used for forming source/drain extension regions having an ultra-shallow junction, thereby avoiding damage on the substrate caused by ion implantation. In addition, a dopant is diffused from the doped space into a semiconductor substrate through annealing to form the source/drain extension regions having an ultra-shallow junction.

Abstract: The present invention provides a semiconductor device, a method of manufacture therefor, and an integrated circuit including the semiconductor device. The semiconductor device may include a well doped with a P-type dopant located over a semiconductor substrate. The semiconductor device may further include a buried layer including the P-type dopant located between the well and the semiconductor substrate, and a gate located over the well.

Abstract: A semiconductor device 1000 may include an element isolation region 14, an n-type field effect transistor 100 and an npn-type bipolar transistor 200 formed on a SOI substrate 10. A p-type body region 50a may be electrically connected to an n-type source region 120. The p-type body region 50a may be electrically connected to a p-type base region 220. An n-type drain region 130 may be electrically connected to an n-type collector region 230. An n-type source region 120 may be formed structurally isolated from an n-type emitter region 210.

Abstract: In a thin film transistor provided with a metallic layer with a light-shading property and a Si layer formed on an insulating layer, a dent for locally thinning the insulating layer is formed on a portion corresponding to a drain region. When the Si layer is recrystallized by means of a laser light irradiation, the dent serves as a crystalline nucleus formation region in order to recrystallize a particular portion earlier than other portions. Recrystallization of melted Si starts from a periphery of a bottom surface of the dent, hence a Si layer formed of a single crystal or uniformed crystal grains which serves as an active region of the TFT can be obtained.

Abstract: A semiconductor device has a MOSFET formed on a single crystalline silicon layer in an SOI structure in which the silicon layer is laminated along with an insulator on a handle wafer. To prevent the body floating effect, a recombination center region is formed connecting to the lower surfaces of source and drain regions of the MOSFET. Consequently, the holes generated within the single crystalline silicon layer just beneath a channel of the MOSFET are injected into the recombination center region by way of the single crystalline silicon layer beneath the source diffusion region and eliminated so that the body floating effect is prevented.

Abstract: A body contact structure utilizing an insulating structure between the body contact portion of the active area and the transistor portion of the active area is disclosed. In one embodiment, the present invention substitutes an insulator for at least a portion of the gate layer in the regions between the transistor and the body contact. In another embodiment, a portion of the gate layer is removed and replaced with an insulative layer in regions between the transistor and the body contact. In still another embodiment, the insulative structure is formed by forming multiple layers of gate dielectric between the gate and the body in regions between the transistor and the body contact. The body contact produced by these methods adds no significant gate capacitance to the gate.

Abstract: According to a semiconductor device of the present invention, a field oxide film is formed so as to cover the main surface of an SOI layer and to reach the main surface of a buried oxide film. As a result, a pMOS active region of the SOI and an nMOS active region of the SOI can be electrically isolated completely. Therefore, latchup can be prevented completely. As a result, it is possible to provide a semiconductor device using an SOI substrate which can implement high integration by eliminating reduction of the breakdown voltage between source and drain, which was a problem of a conventional SOI field effect transistor, as well as by efficiently disposing a body contact region, which hampers high integration, and a method of manufacturing the same.

Abstract: An integrated circuit device comprises an insulation layer formed on a substrate, a plurality of lattice relaxed SiGe layers each formed in an island form on the insulation layer, wherein a maximum size of the island form thereof is 10 &mgr;m or less, one of a strained Si layer, a strained SiGe layer and a strained Ge layer formed on at least one of the plurality of lattice relaxed SiGe layers, and a field effect transistor having a gate electrode and source and drain regions, wherein the gate electrode is formed on one of the strained Si layer, the strained SiGe layer and the strained Ge layer with a gate insulation film is disposed therebetween, and the source and drain regions is formed to sandwich a channel region formed below the gate electrode with the gate insulation film disposed therebetween.

Abstract: An integrated circuit using silicon-on-insulator (SOI) has most of its transistors with their channels (bodies) floating. Some of the transistors, however, must have their channels coupled to a predetermined bias in order to achieve desired operating characteristics. In order to achieve the needed bias, a contact path is provided in the semiconductor layer of the SOI substrate and under an extension of the gate of the transistor. The extension is separated from the semiconductor layer by an insulator that is thicker than that for most of the transistor but advantageously is the same as that used for some of the thick gate insulator devices used, typically, for high voltage applications. This thicker insulator advantageously reduces the capacitance, but does not increase process complexity because it uses an insulator already required by the process.

Abstract: A semiconductor device comprising a source region, a drain region, and a buried insulating film. The buried insulating film is composed of a first part lying below the source and drain region, and a second part lying below the space between the source and drain regions. The first part of the buried insulating film is thicker than the second part. The bottoms of the source and drain regions contact the first part of the buried insulating film.

Abstract: An apparatus and fabrication process for a capacitor formed in conjunction with a dual damascene process. A bottom capacitor plate is electrically connected to an overlying first conductive via formed according to the dual damascene process. A top capacitor plate is connected to an overlying second conductive via. A dielectric material is disposed between the top and the bottom plates. The capacitor is formed by successively forming the bottom plate, the dielectric layer, and the top plate, patterning these layers as required after their formation. The first conductive via is formed over and electrically connected to the bottom plate and the second conductive via is formed over and connected to the top capacitor plate thereby providing for interconnection of the capacitor to other circuit elements by way of the dual damascene conductive runners connected to the conductive vias.

Abstract: A method for crystallizing an amorphous silicon film which includes the steps of: preparing a substrate having the amorphous silicon film, the amorphous silicon film being formed on an intermediate layer in which an inner space exists; applying an energy to the amorphous silicon film in order to crystallize the amorphous silicon film, wherein the step of preparing the substrate includes the steps of: forming a material layer for forming the space on an insulating substrate, forming the intermediate layer to cover the material layer, forming the amorphous silicon film on the intermediate layer, selectively removing the amorphous silicon film and the intermediate layer to expose a part of the material layer for forming space, and removing the material layer for forming space; or forming a material layer for forming the space on an insulating substrate, forming the intermediate layer to cover the material layer, selectively removing the intermediate layer to expose a part of the material layer, removing the mate

Abstract: A MOSFET with low leakage current and method. The MOSFET has a substrate, a channel region, a source/drain region, a gate oxide layer and a conductive layer. The channel region in the substrate has a first region and a second region. The first region has a first threshold voltage and the second region has a second threshold voltage, respectively. The second region is located between the first region and the source/drain region. The first threshold voltage is smaller than the second threshold voltage. The leakage current of the MOSFET has an appropriate reduction by increasing the second threshold voltage of the second region. Significantly, by adjusting the size and position of the second region of the channel region, both the leakage current and the drain current of the MOSFET are readily optimized.

Abstract: A semiconductor device monitor structure is described which can detect localized defects due to floating-body effects, particularly on SOI device wafers. The monitor structure includes a plurality of cells containing PFET or NFET devices, disposed at a perimeter of the structure which is bordered by an insulating region such as shallow trench isolation (STI). Each cell includes polysilicon gate structures having a characteristic spacing given by a first distance, and a portion extending beyond the perimeter a second distance. The cells are constructed in accordance with progressively varying ground rules, so that the first distance and second distance are non-uniform between cells. The cells may be bit fail mapped for single-cell failures, thereby enabling detection of localized defects due to floating-body effects.

Abstract: A semiconductor memory device comprises a trench etched from a substrate below a shallow trench isolation and a doped collar oxide. The device further comprises a buried-strap junction formed adjacent to the shallow trench isolation and above the collar oxide, and a channel stop formed below the buried-strap junction, wherein a junction between the channel stop and the buried-strap junction is formed in the substrate.

Abstract: A semiconductor device of SOI structure comprises a surface semiconductor layer in a floating state, which is stacked on a buried insulating film so as to construct an SOI substrate, source/drain regions of second conductivity type which are formed in the surface semiconductor layer, a channel region of first conductivity type between the source/drain regions and a gate electrode formed on the channel region through a gate insulating film; wherein the surface semiconductor layer has a potential well of the first conductivity type formed therein at and/or near at least one end of the channel region in a gate width direction thereof.

Abstract: In a semiconductor device using a crystalline semiconductor film on a substrate 106 having an insulating surface, impurities are locally implanted into an active region 102 to form a pinning region 104. The pinning region 104 suppresses the spread of a depletion layer from the drain side to effectively prevent the short-channel effect. Also, since a channel forming region 105 is intrinsic or substantially intrinsic, a high mobility is realized.

Abstract: Provided are a Schottky barrier tunnel transistor (SBTT) and a method of fabricating the same. The SBTT includes a buried oxide layer formed on a base substrate layer and having a groove at its upper surface; an ultra-thin silicon-on-insulator (SOI) layer formed across the groove; an insulating layer wrapping the SOI layer on the groove; a gate formed to be wider than the groove on the insulating layer; source and drain regions each positioned at both sides of the gate, the source and drain regions formed of silicide; and a conductive layer for filling the groove. In the SBTT, the SOI layer is formed to an ultra-thin thickness to minimize the occurrence of a leakage current, and a channel in the SOI layer below the gate is completely wrapped by the gate and the conductive layer, thereby improving the operational characteristics of the SBTT.

Abstract: A first well of a first conductivity type is formed in a partial region of the surface layer of a semiconductor substrate. A MOS transistor is formed in the first well. The MOS transistor has a gate insulating film, a gate electrode, and first and second impurity diffusion regions of a second conductivity type on both sides of the gate electrode. A high leak current structure is formed which makes a leak current density when a reverse bias voltage is applied across the first impurity diffusion region and first well become higher than a leak current density when the same reverse bias voltage is applied across the second impurity diffusion region and first well.

Abstract: A transistor fabrication method comprises: sequentially forming a pad oxide film and a silicon nitride film on a semiconductor substrate; etching the substrate to form a trench; sequentially forming a first oxide film within the trench and a cylindrical insulation spacer at a lateral portion of the first oxide film; forming an insulation pattern; etching the silicon nitride film, the insulation pattern and the insulation spacer; removing the pad oxide film; removing the insulation spacer and the first oxide film; sequentially forming source/drain regions and LDD regions at both sides of the trench, under the remaining insulation pattern; forming a second oxide film; sequentially forming a channel stop layer between the LDD regions and a punch stop layer under the channel stop layer; and sequentially forming a gate insulation film and a gate region within the trench and the second oxide layer.

Abstract: The bar-type field effect transistor consists of a substrate, a bar placed above a substrate and a gate and spacer placed above part of the bar.

Abstract: A semiconductor device is provided that includes a semiconductor channel region extending above a semiconductor substrate in a longitudinal direction between a semiconductor source region and a semiconductor drain region, and a gate region extending in the transverse direction, coating the channel region, and insulated from the channel region. The source, channel, and drain regions are formed in a continuous semiconductor layer that is approximately plane and parallel to the upper surface of the substrate. Additionally, the source, drain, and gate regions are coated in an insulating coating so as to provide electrical insulation between the gate region and the source and drain regions, and between the substrate and the source, drain, gate, and channel regions. Also provided is an integrated circuit that includes such a semiconductor device, and a method for manufacturing such a semiconductor device.

Abstract: In a process for manufacturing a thin film transistor having a semiconductor layer constituting source and drain regions and a channel forming region, by the semiconductor layer being made thinner in the source and drain regions than in the channel forming region a structure is realized wherein, at the boundary between the source region and the channel forming region and the boundary between the drain region and the channel forming region, portions where electric field concentrations occur are displaced from the portion where a channel is formed. By reducing the OFF current (the leak current) without also reducing the ON current, a high mutual conductance is realized.

Abstract: A semiconductor substrate that suppresses not only auto doping but also warpage can be provided by disposing an oxide film (4) at a position in a semiconductor substrate (1), so as to be apart from a main surface (1a) and a reverse surface (1b).

Abstract: A semiconductor substrate, for forming a circuit pattern of a semiconductor chip, comprised of a substrate, an insulating film formed on the substrate, and a semiconductor layer formed on the insulating film, wherein the semiconductor layer is isolated by the insulating film for every region formed with a circuit pattern of a semiconductor chip, able to be generally used even if a silicon on insulator or semiconductor on insulator (SOI) layer is isolated by an insulating film, and a process of production of an SOI substrate, enabling a reduction of thickness of the SOI layer and able to suppress the manufacturing costs and variation in the thickness of the SOI layer, comprising forming a groove in a first substrate made of a semiconductor, forming a first insulating film in the groove and on the first substrate, injecting hydrogen ions to form a peeling layer, bonding a second substrate, peeling off the first substrate by heat treatment while leaving the semiconductor layer, and polishing the semiconductor la

Abstract: A method of forming an electrical contact is provided. The method includes forming a gate dielectric layer adjacent a body region of a transistor structure and forming a layer of dielectric material at least partially defining a trench adjacent the body region. The method further includes forming a conductive layer extending into the trench. The method further includes removing a region of the portion of the conductive layer extending into the trench to expose a region of the gate dielectric layer. The method further includes removing the exposed region of the gate dielectric layer to expose a contact portion of the body region. The method further includes filling the trench with a gate material such that a contact portion of the gate material is in direct contact with the contact portion of the body region.

Abstract: The benefits of strained semiconductors are combined with silicon-on-insulator approaches to substrate and device fabrication.

Abstract: A semiconductor integrated circuit includes: a logic circuit section including transistors formed on an SOI substrate; and a partially-depletion-type transistor, which is formed on the SOI substrate as a switching transistor for controlling ON/OFF states of the logic circuit section and which has a body contact portion. The partially-depletion-type transistor has a threshold voltage, which is substantially equal to that of the transistors in the logic circuit section when no potential is applied to the body contact portion and which is higher than that of the transistors in the logic circuit section when a potential is applied to the body contact portion.

Abstract: A silicon-on-insulation (SOI) body contact is formed within a device region of an SOI substrate so that no space of the SOI substrate is wasted for implementing a body contact. The body contact is formed by epitaxially growing silicon and depositing polysilicon. An electrical device can be formed to overlie the body contact. Thus, no additional circuitry or conductive path is required to electrically connect a body contact and a device region. Also, the body contact provides a predictable electrical characteristics without sacrificing the benefits attained from using the SOI substrate and conservation surface space on the semiconductor die.

Abstract: An electrooptical device including a semiconductor device which is formed in a semiconductor layer on an insulating layer in such a manner that floating substrate effects which are essential in a SOI structure is suppressed without reducing the aperture ratio. The thickness of a semiconductor layer in pixel areas is limited to a range equal to or less than 100 nm, p-channel transistors having less floating substrate effects are employed as pixel transistors, and recombination centers are produced by means of implantation of Ar ions, thereby avoiding accumulation of excess carriers, thereby realizing an electrooptical device in which floating substrate effects are suppressed without forming a body contact and which has a high aperture ratio and a low optically induced leakage current.

Abstract: Provided are a semiconductor device and a method for manufacturing the semiconductor device. The semiconductor device includes an isolation insulating film, an epitaxial silicon layer, a junction blocking insulating film, a gate stack, and source and drain junctions. The isolation insulating film is formed on a semiconductor substrate to define an active area. The epitaxial silicon layer is formed in the active area of the semiconductor substrate and surrounded by the isolation insulating film. The junction blocking insulating film is formed in the epitaxial silicon layer. The gate stack is formed over the epitaxial silicon layer so that the junction blocking insulating film is buried under approximately the center of the gate stack. The source and drain junctions are formed adjacent the sidewalls of the gate stack. Accordingly, a short circuit between source/drain junctions in a bulk area caused by the unwanted diffusion of the junctions can be prevented.

Abstract: A semiconductor structure and a method of manufacturing a silicon on insulator (SOI) structure having a silicon germanium (SiGe) layer interposed between the silicon and the insulator. According to one manufacturing method, a first SiGe layer, a silicon layer, and a second SiGe layer are epitaxially grown in sequence over a first substrate, and then an insulating layer is formed on the second SiGe layer. Then, impurity ions are implanted into a predetermined location of the first substrate underlying the first SiGe layer to form an impurity implantation region. A second substrate is bonded to the insulating layer on the first substrate. After the first substrate is separated along the impurity implantation region and removed, the first SiGe layer remaining on the surface of the separated region is removed so that the surface of the silicon layer may be exposed.

Abstract: A ground-plane SOI device including at least a gate region that is formed on a top Si-containing layer of a SOI wafer, said top Si-containing layer being formed on a non-planar buried oxide layer, wherein said non-planar buried oxide layer has a thickness beneath the gate region that is thinner than corresponding oxide layers that are formed in regions not beneath said gate region as well as a method of fabricating the same are provided.

Abstract: A silicon-on-insulator (SOI) gated diode and non-gated junction diode are provided. The SOI gated diode has a PN junction at the middle region under the gate, and which has more junction area than a normal diode. The SOI non-gated junction diode has a PN junction at the middle region thereof, and then also has more junction area than a normal diode. The SOI diodes of the present invention improve the protection level offered for electrical overstress (EOS)/electrostatic discharge (ESD) due to the low power density and heating for providing more junction area than normal ones. The I/O ESD protection circuits, which comprise primary diodes, a first plurality of diodes, and a second plurality of diodes, all of which are formed of the present SOI diodes, could effectively discharge the current when there is an ESD event. And, the ESD protection circuits, which comprise more primary diodes, could effectively reduce the parasitic input capacitance, so that they can be used in the RF circuits or HF circuits.

Abstract: A silicon-on-insulator (SOI) gated diode and non-gated junction diode are provided. The SOI gated diode has a PN junction at the middle region under the gate, thus providing more junction area than a normal diode. The SOI non-gated junction diode has a PN junction at the middle region thereof, and thus also has more junction area than a normal diode. The SOI diodes of the present invention improve the protection level offered for electrical overstress (EOS)/electrostatic discharge (ESD) due to the low power density and heating for providing more junction area than normal ones. The I/O ESD protection circuits, which comprise primary diodes, a first plurality of diodes, and a second plurality of diodes, all of which are formed of the present SOI diodes, could effectively discharge the current when there is an ESD event. And, the ESD protection circuits, which comprise more primary diodes, could effectively reduce the parasitic input capacitance, so that they can be used in the RF circuits or HF circuits.

Abstract: To present a SOI type MOS element excellent in yield, performance and characteristic, easy in manufacture, and low in cost, and a method of manufacturing the same. A SOI type MOS transistor structure comprising polysilicon electrodes 128 for gate, source and drain composed by burying into trench holes 120a, 120b, 120c respectively formed in a semiconductor substrate 110, a gate oxide film 122 formed in the entire inside of the trench hole 120a, N− diffusion layer 124 and N+ diffusion layer 126 formed in the entire inside of the trench holes 120b and 120c, and a thick SiO2 film 114 in a trench hole 113 formed in the semiconductor substrate 110 so as to surround the transistor.

Abstract: A semiconductor memory device comprising: an SOI substrate having a thin silicon layer on top of a buried insulator; and an SRAM comprising four NFETs and two PFETs located in the thin silicon layer, each the NFET and PFET having a body region between a source region and a drain region, wherein the bodies of two of the NFETs are electrically connected to ground. Additionally, the bodies of the two PFETs are electrically connected to VDD.

Abstract: A flat panel display device with improved electrical characteristics and a simplified manufacturing process is disclosed. The device includes a semiconductor layer formed on an insulating substrate; source and drain electrodes directly contacting both end portions of the semiconductor layer, respectively; a pixel electrode having an opening portion formed thereon; a first insulating layer formed over the remaining portion of the insulating substrate except for the opening portion; a gate electrode formed on a portion of the first insulating layer over the semiconductor layer; and source and drain regions formed in both end portions of the semiconductor layer.

Abstract: Methods and apparatus are provided for creating field effect transistor (FET) body connections with high-quality matching characteristics and no area penalty for partially depleted silicon-on-insulator (SOI) circuits. The FET body connections are created for partially depleted silicon-on-insulator (SOI) technologies by forming adjacent FET devices inside a shallow trench shape. The adjacent FET devices share a common diffusion area, such as source or drain. Selectively spacing apart adjacent gate lines form an underpath connecting bodies of the adjacent FET devices. The underpath is defined by forming an undepleted region on top of a buried oxide layer. The adjacent polysilicon gate lines are selectively spaced apart to define a depth of depletion in a shared diffusion region for creating the underpath. Also, adjacent FET devices with connecting bodies can be built by adding an ion implant masking step to the fabrication process. This masking step changes the depletion depth under the shared diffusion area.

Abstract: A semiconductor device comprises an SOI substrate, a trench, a trench capacitor, and a conductive layer. The SOI substrate includes a fist semiconductor region, a buried insulating film formed on the first semiconductor region, and a second semiconductor region formed on the buried insulating film. The trench is of a depth to reach the first semiconductor region, extending from a surface of the second semiconductor region on the SOI substrate and passing through the buried insulating film. The trench capacitor is formed within the trench. The conductive layer is formed in a region between a sidewall portion of the trench and the buried insulating film, and electrically connects the first semiconductor region and the second semiconductor region.

Abstract: A method and structure for a transistor that includes an insulator and a silicon structure on the insulator. The silicon structure includes a central portion and Fins extending from ends of the central portion. A first gate is positioned on a first side of the central portion of the silicon structure. A strain-producing layer could be between the first gate and the first side of the central portion of the silicon structure and a second gate is on a second side of the central portion of the silicon structure.

Abstract: In a SOI substrate, a semiconductor circuit formed in a SOI substrate, and an associated production method, a multilayer barrier layer with a potential barrier and a diffusion barrier is used to reliably prevent diffusion of impurities between element layers. This allows semiconductor circuits to be produced with smaller structure sizes and with a higher integration density.

Abstract: A method and structure for a silicon on insulator (SOI) device with a body contact are provided. The body contact is formed by epitaxial growth from a substrate to the body region of the device. The body contact is self-aligned with the gate of the device and is buried within an isolation region outside of the active area of the device. Thus, the body contact does not increase parasitic capacitance in the device, not does the body contact affect device density. No additional metal wiring or contact holes are required.

Abstract: A silicon oxide insulator (SOI) device includes an SOI layer supported on a silicon substrate. A body region is disposed on the SOI layer, and the body region is characterized by a first conductivity type. Source and drain regions are juxtaposed with the body region, with the source and drain regions being characterized by a second conductivity type. A transition region is disposed near the body region above the SOI layer, and the conductivity type of the transition region is established to be the first conductivity type for suppressing floating body effects in the body region and the second conductivity type for isolating the body region. An ohmic connector contacts the transition region and is connected to a drain power supply when the source and drain are doped with N-type dopants. On the other hand, the power supply is a source power supply when the source and drain are doped with P-type dopants.

Abstract: A semiconductor-on-insulator (SOI) device includes a buried insulator layer and an overlying semiconductor layer. Portions of the insulator layer are doped with the same dopant material, for example boron, as is in corresponding portions of the overlying surface semiconductor layer. A peak concentration of the dopant material may be located in the insulator material, or may be located in a lower portion of the surface semiconductor layer. The dopant material in the insulator layer may prevent depletion of dopant material from portions of the surface semiconductor layer, such as from channel portions of NMOS transistors.

Abstract: An FET device and method of making comprising a first dielectric layer; a substrate layer on the dielectric layer; a channel region of a first conductivity type formed in the substrate layer; a gate formed above the substrate layer over the channel region; FET diffusion regions of a second conductivity type formed in the substrate layer, the diffusion regions each having edges, the edges of the FET diffusion regions being separated by the channel region; and a body contact region of the first conductivity type extending continuously from the channel region. The first conductivity type material in the body contact region is thinner than the first conductivity type material in the channel region. The FET also includes a second dielectric layer formed on the body contact region.

Abstract: The present invention provides, in a TFT, a channel region facing a gate electrode through a gate insulating film, a source electrode connected to the channel region and a drain region connected to the channel region on the side opposite the source region that are formed in a polycrystal semiconductor film that was patterned in island forms. In the channel region, a recombination center is formed for capturing a small number of carriers (holes) by impurities, such as inert-gas, metals, Group III elements, Group IV elements and Group V elements, introduced to a predetermined region in this channel region, or by defects generated due to the introduction of these impurities. The present invention thus provides an arrangement restraining bipolar transistor type behavior to stabilize saturation current and to provide a TFT that can improve reliability.

Abstract: Dot-pattern-like impurity regions 104 are artificially and locally formed on a channel forming region 103. The impurity regions 104 restrain the expansion of a drain side depletion layer toward the channel forming region 103 to prevent the short channel effect. The impurity regions 104 allow a channel width W to be substantially fined, and the resultant narrow channel effect releases the lowering of a threshold value voltage which is caused by the short channel effect.

Abstract: A silicon on insulator substrate is provided to include the following: a handle wafer; a layer of bonding material; a device wafer, the device wafer including at least one buried impurity region extending from the layer of bonding material upward into the device wafer; and an epitaxial silicon layer provided on a second surface of the device wafer. The silicon on insulator substrate with this configuration can be made with a minimal possible thickness.

Abstract: The present invention relates to a semiconductor device including a circuit composed of thin film transistors having a novel GOLD (Gate-Overlapped LDD (Lightly Doped Drain)) structure. The thin film transistor comprises a first gate electrode and a second electrode being in contact with the first gate electrode and a gate insulating film. Further, the LDD is formed by using the first gate electrode as a mask, and source and drain regions are formed by using the second gate electrode as the mask. Then, the LDD overlapping with the second gate electrode is formed. This structure provides the thin film transistor with high reliability.