Abstract: A method of forming a metal oxide semiconductor (MOS) device comprises defining an active area in an unstrained semiconductor layer structure, depositing a hard mask overlying the active area and a region outside of the active area, patterning the hard mask to expose the active area, selectively growing a strained semiconductor layer overlying the exposed active area, and forming a remainder of the MOS device. The active area includes a first doped region of first conductivity type and a second doped region of second conductivity type. The strained semiconductor layer provides a biaxially strained channel for the MOS device.

Abstract: A source trench and a drain trench are asymmetrically formed in a top semiconductor layer comprising a first semiconductor in a semiconductor substrate. A second semiconductor material having a narrower band gap than the first semiconductor material is deposited in the source trench and the drain trench to form a source side narrow band gap region and a drain side narrow band gap region, respectively. A gate spacer is formed and source and drain regions are formed in the top semiconductor layer. A portion of the boundary between an extended source region and an extended body region is formed in the source side narrow band gap region. Due to the narrower band gap of the second semiconductor material compared to the band gap of the first semiconductor material, charge formed in the extended body region is discharged through the source and floating body effects are reduced or eliminated.

Abstract: CMOS integrated circuit devices include an electrically insulating layer and an unstrained silicon active layer on the electrically insulating layer. An insulated gate electrode is also provided on a surface of the unstrained silicon active layer. A Si1-xGex layer is also disposed between the electrically insulating layer and the unstrained silicon active layer. The Si1-xGex layer forms a first junction with the unstrained silicon active layer and has a graded concentration of Ge therein that decreases monotonically in a first direction extending from a peak level towards the surface of the unstrained silicon active layer. The peak Ge concentration level is greater than x=0.15 and the concentration of Ge in the Si1-xGex layer varies from the peak level to a level less than about x=0.1 at the first junction. The concentration of Ge at the first junction may be abrupt. More preferably, the concentration of Ge in the Si1-xGex layer varies from the peak level where 0.2<x<0.

Abstract: A semiconductor device comprising a gate electrode formed on a gate dielectric layer formed on a semiconductor film. A pair of source/drain regions are formed adjacent the channel region on opposite sides of the gate electrode. The source and drain regions each comprise a semiconductor portion adjacent to and in contact with the semiconductor channel and a metal portion adjacent to and in contact with the semiconductor portion.

Abstract: A method for forming a low temperature polysilicon thin film transistor with a low doped drain structure comprises: a) forming a polysilicon island on a substrate; b) forming a dielectric layer, a metal layer and a cap layer in sequence cover to the polysilicon island; c) forming a photo-resist patterened layer on the cap layer; d) removing the portion of the metal layer and the portion of the cap layer which are uncovered by the photo-resist patterned layer, and the remaining metal layer is uncovered by the remaining cap layer with a predetermined distance at the same side; e) performing a high concentration ion-doping using the metal layer as a mask; f) removing the portion of the metal layer uncovered by the remaining cap layer; and g) performing a low concentration ion-doping using the metal layer as a mask.

Abstract: An extremely-thin silicon-on-insulator transistor is provided that includes a buried oxide layer above a substrate, a silicon layer above the buried oxide layer, a gate stack on the silicon layer, a nitride liner on the silicon layer and adjacent to the gate stack, an oxide liner on and adjacent to the nitride liner, and raised source/drain regions. The gate stack includes a high-k oxide layer on the silicon layer and a metal gate on the high-k oxide layer. Each of the raised source/drain regions has a first part comprising a portion of the silicon layer, a second part adjacent to parts of the oxide liner and the nitride liner, and a third part above the second part. Also provided is a method for fabricating an extremely-thin silicon-on-insulator transistor.

Abstract: A transistor forming method includes forming a dielectric spacer in a trench surrounding an active area island, forming line openings through the spacer, and forming a gate line extending through the line openings, over opposing sidewalls, and over a top of the fin. Source/drain regions are in the fin. Another method includes forming an interlayer dielectric over areas of the fin intended for source/drain regions, forming contact openings through the interlayer dielectric, and forming a source/drain plug in contact with an exposed portion of the spacer and in electrical connection with the top, one of opposing endwalls, and both of the opposing sidewalls of the fin.

Abstract: A memory device includes an active area protruding from a semiconductor substrate. A recess is formed in the active area. A field oxide layer is formed on the semiconductor substrate. A gate electrode extends across the active area while being overlapped with the recess. A gate insulation layer is interposed between the gate electrode and the active area. Source and drain areas are formed in the active area. The transistor structure above defines a recessed transistor structure if it is sectioned along a source-drain line and defines a Fin transistor structure if it is sectioned along a gate line. The transistor structure ensures sufficient data retention time and improves the current drivability while lowering the back bias dependency of a threshold voltage.

Abstract: In one embodiment, the invention is a complementary metal-oxide-semiconductor device with an embedded stressor. One embodiment of a field effect transistor includes a silicon on insulator channel, a gate electrode coupled to the silicon on insulator channel, and a stressor embedded in the silicon on insulator channel and spaced laterally from the gate electrode, where the stressor is formed of a silicon germanide alloy whose germanium content gradually increases in one direction.

Abstract: In the fabrication of semiconductor devices such as active matrix displays, the need to pattern resist masks in photolithography increases the number of steps in the fabrication process and the time required to complete them and consequently represents a substantial cost. This invention provides a method for forming an impurity region in a semiconductor layer 303 by doping an impurity element into the semiconductor layer self-aligningly using as a mask the upper layer (a second conducting film 306) of a gate electrode formed in two layers. The impurity element is doped into the semiconductor layer through the lower layer of the gate electrode (a first conducting film 305), and through a gate insulating film 304. By this means, an LDD region 313 of a GOLD structure is formed in the semiconductor layer 303.

Abstract: A selectively strained MOS device such as selectively strained PMOS device making up an NMOS and PMOS device pair without affecting a strain in the NMOS device the method including providing a semiconductor substrate comprising a lower semiconductor region, an insulator region overlying the lower semiconductor region and an upper semiconductor region overlying the insulator region; patterning the upper semiconductor region and insulator region to form a MOS active region; forming an MOS device comprising a gate structure and a channel region on the MOS active region; and, carrying out an oxidation process to oxidize a portion of the upper semiconductor region to produce a strain in the channel region.

Abstract: The present invention makes it is possible to provide a manufacturing method of a semiconductor device by which damage by plasma process or doping process during a LDD formation process can be reduced as much as possible. Charge density to be stored in a gate electrode and the damage of an element due to plasma are reduced as much as possible during anisotropic etching of an LDD formation process, by forming an LDD region in the state that a conductive protecting film is formed to cover a whole area of a substrate. Further, damage by charged particles during a process of doping a high concentration of impurity is also reduced.

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: An insulated gate field effect semiconductor device comprising a substrate having provided thereon a thin-film structured insulated gate field effect semiconductor device, said device being characterized by that it comprises a metal gate electrode and at least the side thereof is coated with an oxide of the metal. The insulated gate field effect semiconductor device according to the present invention is also characterized by that the contact holes for the extracting contacts of the source and drain regions are provided at about the same position of the end face of the anodically oxidized film established at the side of the gate. Furthermore, the present invention provides a method for forming insulated gate field effect semiconductor devices using less masks.

Abstract: The field effect transistor comprises a source and a drain connected by a channel controlled by a gate electrode separated from the channel by a gate insulator. The channel is formed by a diamond-like carbon layer. The method for making the transistor successively comprises deposition of a diamond-like carbon layer on a substrate, deposition of a gate insulating layer and deposition of at least one conducting layer. The conducting layer is etched to form the gate electrode. Then an insulating material is deposited on the flanks of the gate electrode to form a lateral insulator. Then the gate insulating layer is etched and the diamond-like carbon layer is etched so as to delineate the channel. Then a semi-conducting material designed to form the source and a semi-conducting material designed to form the drain are deposited on each side of the channel.

Abstract: A multi-channel type thin film transistor includes a gate electrode over a substrate extending along a first direction, a plurality of active layers parallel to and spaced apart from each other extending along a second direction crossing the first direction, and source and drain electrodes spaced apart from each other with respect to the gate electrode and extending along the first direction, wherein each of the plurality of active layers includes a channel region overlapped with the gate electrode, a source region, a drain region, and lightly doped drain (LDD) regions, one between the channel region and the source region and another one between the channel region and the drain region, wherein the LDD regions of the adjacent active layers have different lengths from each other.

Abstract: In accordance with an embodiment of the invention, there is an integrated circuit device having a complementary integrated circuit structure comprising a first MOS device. The first MOS device comprises a source doped to a first conductivity type, a drain extension doped to the first conductivity type separated from the source by a gate, and an extension region doped to a second conductivity type underlying at least a portion of the drain extension adjacent to the gate. The integrated circuit structure also comprises a second complementary MOS device comprising a dual drain extension structure.

Abstract: Upon manufacture of a semiconductor device provided with a source region and a drain region formed by activating, through anneal, an n-type first dopant ion-implanted in a p-type device forming area provided in a semiconductor layer formed on an insulator, and a body region, (a) ion implantation of Ar in a boundary region between the source and drain regions to be formed, which corresponds to a region lying in a predeterminate area for forming the body region, and (b) high-temperature anneal for partly recovering crystal defects produced by the ion implantation of the Ar at a temperature higher than the anneal for activation of the first dopant are carried out prior to the ion-implantation of the first dopant.

Abstract: In various aspects, a MOSFET may include an active region of a first conductivity type provided on an insulating layer, the active region having a first portion and a second portion, the first portion being thicker than the second portion; a base region of the first conductivity type provided on the insulating layer, the base region having a higher impurity concentration than the first portion of the active region, the base region being in contact with the first portion of the active region and the insulating layer; a drain region of a second conductivity type provided on the insulating layer, the drain region being in contact with the second portion of the active region and the insulating layer, the drain region being spaced from the base region; a source region of the second conductivity type provided on a surface of the base region; a gate insulating layer provided on the source region, the base region, the active region and the drain region; and a gate electrode provided on the gate insulating layer.

Abstract: A structure and method for fabricating a transistor structure is provided. The method comprises the steps of: (a) providing a substrate including a semiconductor-on-insulator (“SOI”) layer separated from a bulk region of the substrate by a buried dielectric layer. (b) first implanting the SOI layer to achieve a predetermined dopant concentration at an interface of the SOI layer to the buried dielectric layer. and (c) second implanting said SOI layer to achieve predetermined dopant concentrations in a polycrystalline semiconductor gate conductor (“poly gate”) and in source and drain regions disposed adjacent to the poly gate, wherein a maximum depth of the first implanting is greater than a maximum depth of the second implanting.

Abstract: A method is provided to fabricate a semiconductor device, where the method includes providing a substrate comprised of crystalline silicon; implanting a ground plane in the crystalline silicon so as to be adjacent to a surface of the substrate, the ground plane being implanted to exhibit a desired super-steep retrograde well (SSRW) implant doping profile; annealing implant damage using a substantially diffusionless thermal annealing to maintain the desired super-steep retrograde well implant doping profile in the crystalline silicon and, prior to performing a shallow trench isolation process, depositing a silicon cap layer over the surface of the substrate. The substrate may be a bulk Si substrate or a Si-on-insulator substrate. The method accommodates the use of an oxynitride gate stack structure or a high dielectric constant oxide/metal (high-K/metal) gate stack structure.

Abstract: A method for forming a semiconductor structure includes providing a semiconductor substrate, forming a gate stack on the semiconductor substrate, and epitaxially growing a lightly-doped source/drain (LDD) region adjacent the gate stack, wherein carbon is simultaneously doped into the LDD region.

Abstract: In the invention, a low concentration impurity region is formed between a channel formation region and a source region or a drain region in a semiconductor layer and covered with a gate electrode layer in a thin film transistor The semiconductor layer is doped obliquely to the surface thereof using the gate electrode layer as a mask to form the low concentration impurity region. The semiconductor layer is formed to have an impurity region including an impurity element for imparting one conductivity which is different from conductivity of the thin film transistor, thereby being able to minutely control the properties of the thin film transistor.

Abstract: A manufacturing method of a TFT is provided. A polysilicon island, a gate insulating layer and a gate are sequentially formed on a substrate. LDD regions are formed in the polysilicon island below two sides of the gate, while the polysilicon island below the gate is a channel region. A metal oxidation process is performed to form a gate oxidation layer on the gate. A source and a drain are formed in the polysilicon island below two sides of the gate oxidation layer. A dielectric layer is formed on the gate insulating layer. Portions of the dielectric layer and the gate insulating layer are removed to expose a portion of the source and drain, and a patterned dielectric layer and a patterned gate insulating layer are formed. A source and a drain conductive layers electrically respectively connected to the source and the drain are formed on the patterned dielectric layer.

Abstract: A thin film transistor having a LDD structure that may improve its channel reliability and output characteristics. A semiconductor layer comprises source/drain regions, a channel region positioned between the source/drain regions, and an LDD region positioned between the channel region and a source/drain region, wherein a projected range of ions doped on the semiconductor layer extends to a first depth from the surface of the semiconductor layer in the LDD region.

Abstract: An extremely-thin silicon-on-insulator transistor is provided that includes a buried oxide layer above a substrate, a silicon layer above the buried oxide layer, a gate stack on the silicon layer, a nitride liner on the silicon layer and adjacent to the gate stack, an oxide liner on and adjacent to the nitride liner, and raised source/drain regions. The gate stack includes a high-k oxide layer on the silicon layer and a metal gate on the high-k oxide layer. Each of the raised source/drain regions has a first part comprising a portion of the silicon layer, a second part adjacent to parts of the oxide liner and the nitride liner, and a third part above the second part. Also provided is a method for fabricating an extremely-thin silicon-on-insulator transistor.

Abstract: A method for fabricating a liquid crystal display (LCD) device comprises forming an active pattern and a data line on a substrate, the active pattern including a source, a drain, and a channel regions; a first insulation film on a portion of the substrate; forming a gate electrode in a portion of the active pattern where the first insulation film is formed; a second insulation film on the substrate; forming a plurality of first contact holes exposing a portion of the source and drain regions and a second contact hole exposing a portion of the data line; forming a source electrode from a transparent conductive material connected to a source region within the respective first contact hole and a data line within the second contact hole; and forming a pixel and a drain electrodes from the transparent conductive material connected to a drain region within the respective first contact hole.

Abstract: A source trench and a drain trench are asymmetrically formed in a top semiconductor layer comprising a first semiconductor in a semiconductor substrate. A second semiconductor material having a narrower band gap than the first semiconductor material is deposited in the source trench and the drain trench to form a source side narrow band gap region and a drain side narrow band gap region, respectively. A gate spacer is formed and source and drain regions are formed in the top semiconductor layer. A portion of the boundary between an extended source region and an extended body region is formed in the source side narrow band gap region. Due to the narrower band gap of the second semiconductor material compared to the band gap of the first semiconductor material, charge formed in the extended body region is discharged through the source and floating body effects are reduced or eliminated.

Abstract: A semiconductor device includes: a first semiconductor region formed on a substrate and having an upper surface and a side surface; a first impurity region of a first conductivity type formed in an upper portion of the first semiconductor region; a second impurity region of a first conductivity type formed in a side portion of the first semiconductor region; and a gate insulating film formed so as to cover at least a side surface and an upper corner of a predetermined portion of the first semiconductor region. A radius of curvature r? of an upper corner of a portion of the first semiconductor region located outside the gate insulating film is greater than a radius of curvature r of an upper corner of a portion of the first semiconductor region located under the gate insulating film and is less than or equal to 2r.

Abstract: A thin-film transistor includes a semiconductor thin film provided on an insulating surface of a support substrate, a gate insulator provided on the semiconductor thin film, and a gate electrode layer formed on the semiconductor thin film with the gate insulator interposed therebetween. The semiconductor thin film includes a channel region disposed below the gate electrode layer, and source and drain regions disposed on both sides of the channel region. The source region has an impurity concentration profile in which an impurity concentration is lowered from an interface with the gate insulator toward an interface with the support substrate in a thickness direction of the semiconductor thin film. The impurity concentration near the support substrate is lower than the impurity concentration near the gate insulator by a factor of 100 or more in the impurity concentration profile of the source region.

Abstract: In a semiconductor device including a laminate of a first insulating layer, a crystalline semiconductor layer, and a second insulating layer, characteristics of the device are improved by determining its structure in view of stress balance. In the semiconductor device including an active layer of the crystalline semiconductor layer having tensile stress on a substrate, tensile stress is given to the first insulating layer formed to be in close contact with a surface of the semiconductor layer at a substrate side, and compressive stress is given to the second insulating layer formed to be in close contact with a surface of the semiconductor layer at a side opposite to the substrate side.

Abstract: A thin film transistor substrate includes a thin film transistor of a first conductivity type, a semiconductor layer having a channel region of the first conductivity type placed between the source/drain regions, a gate electrode formed to an opposite face to the semiconductor layer with an gate insulating film interposed therebetween, an opening in the gate electrode corresponding to both edges in a channel width direction of the channel region. In the channel region corresponding to the opening, a highly concentrated impurity region having a higher impurity concentration of the first conductivity type than the channel corresponding to the gate electrode is formed.

Abstract: A highly responsive semiconductor device in which the subthreshold swing (S value) is small and reduction in on-current is suppressed is manufactured. A semiconductor layer in which a thickness of a source region or a drain region is larger than that of a channel formation region is formed. A semiconductor layer having a concavo-convex shape which is included in the semiconductor device is formed by the steps of forming a first semiconductor layer over a substrate; forming a first insulating layer and a conductive layer over the first semiconductor layer; forming a second insulating layer over a side surface of the conductive layer; forming a second semiconductor layer over the first insulating layer, the conductive layer and the second insulating layer; etching the second semiconductor layer using a resist formed partially as a mask; and performing heat treatment to the first semiconductor layer and the second semiconductor layer.

Abstract: Source and drain extension regions and source side halo region and drain side halo region are formed in a top semiconductor layer aligned with a gate stack on an SOI substrate. A deep source region and a deep drain region are formed asymmetrically in the top semiconductor layer by an angled ion implantation. The deep source region is offset away from one of the outer edges of the at least spacer to expose the source extension region on the surface of the semiconductor substrate. A source metal semiconductor alloy is formed by reacting a metal layer with portions of the deep source region, the source extension region, and the source side halo region. The source metal semiconductor alloy abuts the remaining portion of the source side halo region, providing a body contact tied to the deep source region to the partially depleted SOI MOSFET.

Abstract: A method is provided for fabricating a silicon (Si)-on-insulator (SOI) double-diffused metal oxide semiconductor transistor (DMOST) with a stepped channel thickness. The method provides a SOI substrate with a Si top layer having a surface. A thinned area of the Si top layer is formed, and a source region is formed in the thinned Si top layer area. The drain region is formed in an un-thinned area of the Si top layer. The channel has a first thickness adjacent the source region with first-type dopant, and a second thickness, greater than the first thickness, adjacent the drain region. The channel also has a sloped thickness between the first and second thicknesses. The second and sloped thicknesses have a second-type dopant, opposite of the first-type dopant. A stepped gate overlies the channel.

Abstract: Superior control of short-channel effects for an ultra-thin semiconductor-on-insulator field effect transistor (UTSOI-FET) is obtained by performing a halo implantation immediately after a gate reoxidation step. An offset is then formed and thereafter an extension implantation process is performed. This sequence of processing steps ensures that the halo implant is laterally separated from the extension implant by the width of the offset spacer. This construction produces equivalent or far superior short channel performance compared to conventional UTSOI-FETs. Additionally, the above processing steps permit the use of lower halo doses as compared to conventional processes.

Abstract: The present invention is characterized in that a transistor with its L/W set to 10 or larger is employed, and that |VDS| of the transistor is set equal to or larger than 1 V and equal to or less than |VGS?Vth|. The transistor is used as a resistor so that the resistance of a light emitting element can be held by the transistor. This slows down an increase in internal resistance of the light emitting element and the resultant current value reduction. Accordingly, a change with time in light emission luminance is reduced and the reliability is improved.

Abstract: A trilayer resist (TLR) patterning scheme is provided to enable gate conductors, particularly polySi gate conductors, with critical dimensions (CDs) of less than 40 nm and minimal LER and LWR. In accordance with the present invention, the inventive patterning scheme utilizes an organic/inorganic/organic multilayer stack instead of an organic layer used in the prior art. The top organic layer of the inventive TLR is a photoresist material such as a 193 nm photoresist that is located atop an antireflective coating (ARC), which is also comprised of an organic material. The middle inorganic layer of the TLR comprises any oxide layer such as, for example, a low temperature (less than or equal to 250° C.) chemical vapor deposited (CVD) oxide, an oxide derived from TEOS (tetraethylorthosilicate), silicon oxide, a silane oxide, or a Si-containing ARC material.

Abstract: A method of forming a transistor including: forming a gate oxide layer pattern and gate polysilicon layer pattern on a silicon substrate; forming a low energy ion implantation region aligned with both sidewalls of the gate polysilicon layer pattern; forming an amorphous region at a lower part of both sidewalls of the gate polysilicon layer pattern; reducing a channel length by removing the amorphous region so as to form a notch at a lower part of both sidewalls of the gate polysilicon layer pattern; forming a gate spacer at both sidewalls of the gate polysilicon layer pattern; and forming a high energy ion implantation region by high energy ion implantation of source/drain impurities into an entire surface of the silicon substrate including the gate polysilicon layer pattern and gate spacer.

Abstract: A thin film transistor substrate is provided whose structure allows for the formation of (i) a thick gate insulating film, (ii) a high pressure resistance TFT having a LDD region of a GOLD structure, and (iii) a low voltage TFT having a thin gate insulating film, with less number of production steps.

Abstract: A manufacturing method of a thin film transistor is provided. A buffer layer is formed on a substrate, and then a first and a second poly-silicon island are formed thereon. A gate-insulating layer is formed on the substrate, and a first and a second gate are formed thereon. A sacrificed layer is formed on the substrate and a photo-resist layer is formed thereon. The sacrificed layer above the first poly-silicon island is removed by using the photo-resist layer as a mask. A first ion implantation process is performed to form a first source/drain. The photo-resist layer is removed and a second ion implantation process is performed to form a second source/drain. At the same time, the second ion implantation process is used to implant ions into the buffer layer below the two sides of the second gate. A lightly-doped ion implantation process is performed after removing the sacrificed layer.

Abstract: A recessed-gate thin-film transistor (RG-TFT) with a self-aligned lightly doped drain (LDD) is provided, along with a corresponding fabrication method. The method deposits an insulator overlying a substrate and etches a trench in the insulator. The trench has a bottom and sidewalls. An active silicon (Si) layer is formed overlying the insulator and trench, with a gate oxide layer over the active Si layer. A recessed gate electrode is then formed in the trench. The TFT is doped and LDD regions are formed in the active Si layer overlying the trench sidewalls. The LDD regions have a length that extends from a top of the trench sidewall, to the trench bottom, with a doping density that decreases in response to the LDD length. Alternately stated, the LDD length is directly related to the depth of the trench.

Abstract: Method for producing a first SOI field effect transistor with predetermined transistor properties by forming a laterally delimited layer sequence with a gate-insulating layer and a gate region on an undoped substrate, forming a spacer layer having a predetermined thickness, on at least a portion of the sidewalls of the laterally delimited layer sequence, and forming two source/drain regions having a predetermined dopant concentration profile, by introducing dopant into two surface regions of the substrate which are adjoined by the spacer layer, the layer sequence and the spacer layer forming a shading structure that prevents dopant from being introduced into a surface region of the substrate between the two source/drain regions, wherein the predetermined transistor properties of the first SOI field effect transistor are set by setting the thickness of the spacer layer and by setting the dopant concentration profile.

Abstract: A method for manufacturing a thin film transistor substrate includes (a) a step of forming a plurality of island-like semiconductor films (13) above an insulating transparent substrate (10); (b) a step of forming a gate insulating film (21) on each of the island-like semiconductor films (13); (c) a step of forming first conductivity type LDD regions on both sides in the first island-like semiconductor film (13) by leaving a channel region and forming a first conductivity type normally-on channel region having an impurity density equivalent to that of the LDD region in the second island-like semiconductor film (13); (d) a step of forming a first gate electrode (32a) partially covering the LDD region and forming a second gate electrode (33a) above the normally-on channel region, and (e) a step of forming a first conductivity type source/drain region having an impurity density higher than that of the LDD region in regions on the both sides of the gate electrode.

Abstract: A semiconductor film, which is located over a gate electrode for forming a channel region between a source electrode and a drain electrode, has a width greater than a width of the source electrode and a width of the drain electrode located over the gate electrode. Irregularities are formed in a width direction of the semiconductor film on both edge portions in the channel region.

Abstract: The first source and drain regions are formed in an upper surface of a SiGe substrate. The first source and drain regions containing an N type impurity. Vacancy concentration in the first source and drain regions are reduced in order to reduce diffusion of the N type impurity contained in the first source and drain regions. The vacancy concentration is reduced by an interstitial element or a vacancy-trapping element in the first source and drain regions. The interstitial element or the vacancy-trapping element is provided by ion-implantation.

Abstract: There is provided a semiconductor device including a semiconductor circuit formed by semiconductor elements having an LDD structure which has high reproducibility, improves the stability of TFTs and provides high productivity and a method for manufacturing the same. In order to achieve the object, the design of a second mask is appropriately determined in accordance with requirements associated with the circuit configuration to make it possible to form a desired LDD region on both sides or one side of the channel formation region of a TFT.

Abstract: A semiconductor device having a novel structure by which the operating characteristics and reliability are improved and a manufacturing method thereof. An island-shaped semiconductor layer provided over a substrate, including a channel formation region provided between a pair of impurity regions; a first insulating layer provided so as to be in contact with the side surface of the semiconductor layer; a gate electrode provided over the channel formation region so as to get across the semiconductor layer; and a second insulating layer provided between the channel formation region and the gate electrode are included. The semiconductor layer is locally thinned, the channel formation region is provided in the thinned region, and the second insulating layer covers the first insulating layer provided on the side surface of the semiconductor layer at least in the region which overlaps with the gate electrode.

Abstract: It is an object to improve operation characteristics and reliability of a semiconductor device. A semiconductor device which includes an island-shaped semiconductor film having a channel-formation region, a first low-concentration impurity region, a second low-concentration impurity region, and a high-concentration impurity region including a silicide layer; a gate insulating film; a first gate electrode overlapping with the channel-formation region and the first low-concentration impurity region with the gate insulating film interposed therebetween; a second gate electrode overlapping with the channel-formation region with the gate insulating film and the first gate electrode interposed therebetween; and a sidewall formed on side surfaces of the first gate electrode and the second gate electrode. In the semiconductor device, a thickness of the gate insulating film is smaller in a region over the second low-concentration impurity region than in a region over the first low-concentration impurity region.

Abstract: In the semiconductor memory of the present invention, the impurity concentration of the high-doped region in the drain region is lower than that of the high-doped region in the source region. The drain region having a lower impurity concentration suppresses the GIDL leakage. The source region having a higher impurity concentration suppresses the leakage of stored charge to between the body and the source region. As a result, the semiconductor memory is enabled to have a memory cell with excellent data holding characteristic.