Abstract: A compact metal oxide semiconductor (MOS) device has its channel region formed by the lateral extension of two high voltage (HV) regions. The two HV regions are implanted into a well region and, as a result of an annealing process, undergo outdiffusion and merge together into a single channel region. The resulting channel region has a dopant concentration that is less than the dopant concentrations of the individual HV regions. The compact MOS device exhibits a low threshold voltage characteristic.

Abstract: A semiconductor device has a first semiconductor element and a second semiconductor element formed on a semiconductor substrate. The second semiconductor element is operated with a first voltage. The first semiconductor element is operated with a second voltage that is higher than the first voltage. The pairs of impurity regions of the first and second semiconductor elements respectively have first impurity areas and second impurity areas. Each of the first impurity areas indicative of a predetermined impurity concentration by an impurity indicative of a conductivity type opposite to a conductivity type of the semiconductor substrate. The second impurity areas extend toward their corresponding gates from the first impurity areas. The second impurity areas indicate the same conductivity type as the first impurity areas and are indicative of an impurity concentration lower than the concentration of the first impurity area.

Abstract: A field effect transistor having a doped region in the substrate immediately underneath the gate of the transistor and interposed between the source and drain of the transistor is provided. The doped region has a retrograde dopant profile such that the doping concentration immediately adjacent the gate is selected to allow for the formation of a channel when a threshold voltage is applied to the gate thereby eliminating the need for an enhancement doping step during formation of the transistor. The retrograde doping profile increases with the depth into the substrate which inhibits stray currents from traveling between the source and drain of the transistor in the absence of the formation of a channel as a result of voltage being applied to the gate of the transistor.

Abstract: The process rules for manufacturing semiconductor devices such as MOSFET's are modified to provide dual work-function doping following the customary gate sidewall oxidation step, greatly reducing thermal budget and boron penetration concerns. The concern of thermal budget is further significantly reduced by a device structure which allows a reduced gap aspect ratio while maintaining low sheet resistance values. A reduced gap aspect ratio also relaxes the need for highly reflowable dielectric materials and also facilitates the use of angled source-drain (S-D) and halo implants. Also provided is a novel structure and process for producing a MOSFET channel, lateral doping profile which suppresses short channel effects while providing low S-D junction capacitance and leakage, as well as immunity to hot-carrier effects. This also affords the potential for reduction in the contact stud-to-gate conductor capacitance, because borderless contacts can be formed with an oxide gate sidewall spacer.

Abstract: A method for fabricating a high voltage transistor includes the steps of: forming a plurality of drift regions on a semiconductor substrate of a first conductive type; implanting drift ions of a second conductive type into surfaces of the drift regions of the semiconductor substrate at a first depth; implanting drift ions of the second conductive type into the surfaces of the drift regions of the semiconductor substrate at a second depth deeper than the first depth; implanting first conductive channel stop ions into the semiconductor substrate thereby forming a space between the semiconductor substrate and the drift regions; forming a device isolation film on a surface of the semiconductor substrate into which the channel stop ions are implanted; forming a gate electrode by inserting a gate insulating film on the semiconductor substrate between the drift regions; and forming a source/drain impurity diffusion region of a second conductive type in the surface of the semiconductor substrate at both sides of the

Abstract: A system for estimating a plasma damage for subsequent layout design of a semiconductor device includes an antenna ratio extraction unit for extracting an antenna ratio from each of existing provisional layout patterns to be exposed to plasma in each of plasma processes. An index calculation unit is connected to the antenna ratio extraction unit for receiving the antenna ratio extracted by the antenna ratio extraction unit and calculating an individual damage index representing a degree of a plasma damage in accordance with the antenna ratio. An index addition unit is connected to the index calculation unit for receiving the individual damage indexes from the index calculation unit and adding the individual damage indexes to estimate a plasma damage.

Abstract: A method of fabricating an integrated circuit with locally confined deep pocket regions utilizes a dummy or sacrificial gate spacer. Dopants are provided through the openings associated with sacrificial spacers to form the pocket regions. The dopants are provided after silicidation. The openings can be filled with spacers. The process can be utilized for P-channel or N-channel metal oxide field semiconductor effect transistors (MOSFETS).

Abstract: The present invention provides a double gate transistor and a method for forming the same that facilitates the formation of different transistors having different threshold voltages. The embodiments of the present invention form transistors having different body widths. By forming double gate transistors with different body widths, the preferred embodiment forms double gate transistors that have different threshold voltages, without adding excessive process complexity. The preferred embodiment of the present invention is implemented using a fin type double gated structure. In a fin type structure, the double gates are formed on each side of the body, with the body being disposed horizontally between the gates.

Abstract: A method for creating a self-aligned channel implant with elevated source/drain areas. Forming a thin dielectric layer on top of a silicon substrate, a thick layer of oxide is deposited over this dielectric. An opening is exposed and etched through the layer of oxide, through the dielectric and into the underlying silicon substrate creating a shallow trench in the substrate. By performing the channel implant LDD implant, pocket implant, forming the gate spacers and electrode, removing the thick layer of oxide and forming the SID regions a gate electrode has been created with elevated SID regions. By forming the gate spacers, performing channel implant, forming the gate electrode, removing the thick layer of oxide and performing SID implant a gate electrode has been created with elevated SID regions and disposable spacers.

Abstract: A method for creating a self-aligned channel implant with elevated source/drain areas. Forming a thin dielectric layer on top of a silicon substrate, a thick layer of oxide is deposited over this dielectric. An opening is exposed and etched through the layer of oxide, through the dielectric and into the underlying silicon substrate creating a shallow trench in the substrate. By performing the channel implant LDD implant, pocket implant, forming the gate spacers and electrode, removing the thick layer of oxide and forming the S/D regions a gate electrode has been created with elevated S/D regions. By forming the gate spacers, performing channel implant, forming the gate electrode, removing the thick layer of oxide and performing S/D implant a gate electrode has been created with elevated S/D regions and disposable spacers.

Abstract: A method for forming a self-aligned local-halo metal-oxide-semiconductor device is provided. The present method is characterized in that a pair of first sidewall spacers is firstly formed on opposite sides of a gate electrode over a semiconductor substrate, and then a pair of second sidewall spacers is formed, each of which formed on one side of each first sidewall spacer. Next, a raised source/drain is formed upward on the substrate between each shallow trench isolation and each second sidewall spacer. Thereafter, the pair of second sidewall spacers is stripped away. Then, the gate electrode and raised source/drain act as the self-aligned ion implant masks, a LDD/Halo implantation is performed to form a local LDD/Halo diffusion region between each shallow trench isolation and each of the first sidewall spacers.

Abstract: Semiconductor device and method for fabricating the same, the device including a semiconductor substrate, a recessed channel region recessed below a surface of the semiconductor substrate, and a gate oxide film formed on the recessed channel region, a first and a second lightly doped impurity regions in surfaces of the substrate adjacent to, and on both sides of the recessed channel region respectively, and a first and a second highly doped impurity regions adjacent to the first and second lightly doped impurity regions, respectively, inverted sidewalls on the first and second lightly doped impurity regions each having a round in a side of the recessed channel region, and a gate electrode both on the inverted sidewalls and the recessed channel region, whereby securing a fabrication allowance and improving a device packing density.

Abstract: The tradeoff between breakdown voltage and on-resistance for LDMOS devices has been improved by having two epitaxial N− regions instead of the single epitaxial N− region that is used by devices of the prior art. The resistivities and thicknesses of these two N− regions are chosen so that their mean resistivity is similar to that of the aforementioned single N− layer. A key feature is that the lower N− layer (i.e. the one closest to the P− substrate) has a resistivity that is greater than that of the upper N− layer. If these constraints are met, as described in greater detail in the specification, improvements in breakdown voltage of up to 60% can be achieved without having to increase the on resistance. A process for manufacturing the device is also described.

Abstract: A gate insulating film and gate electrodes are formed on a substrate containing N-type impurities such as P or As. Under the gate insulating film is a gate region on both sides of which are a first and a second source drain region. The gate region is furnished in its central part with a high-concentration channel injection region containing N-type impurities at a concentration higher than that of the substrate. Between the high-concentration channel injection region on the one hand and the first and the second source drain region and on the other hand, there are formed a first and a second low-concentration channel injection region and having substantially the same impurity concentration as that of the substrate.

Abstract: A method is provided for processing a semiconductor wafer having a chip region where chips are formed and a non-chip region where chips are not normally formed. The method includes the steps of forming trench isolation regions in the semiconductor wafer, and forming dummy trench isolation regions in at least a part of the non-chip region of the semiconductor wafer.

Abstract: A method of fabricating a field effect transistor including doping a continuous blanket layer in a semiconductor substrate structure adjacent the surface to include a source area and a drain area spaced from the source area. A high dielectric constant insulator layer is positioned on the surface of the semiconductor substrate structure overlying the continuous blanket layer to define a gate area between the source and drain areas. A gate contact on the insulator layer is selected to provide a work function difference that depletes the doped layer beneath the insulator layer. Further, the doped layer depth and dosage are designed such that the doped layer is depleted beneath the insulator layer by the selected work function difference of the gate contact and the semiconductor substrate.

Abstract: A fabrication method for a mask read-only memory includes forming an oxide layer on a provided substrate. A first mask layer is formed on the oxide layer, followed by performing a first ion implantation to form a plurality of equally spaced bit lines. A thermal process is further conducted to convert the oxide layer to a denser oxide layer. A plurality of word lines, which is perpendicular to the bit lines, is formed on the denser oxide layer. A second mask layer is formed on the plurality of the word lines, exposing the channel to be coded. A second ion implantation is conducted on the channel to complete the fabrication of the mask read-only memory device.

Abstract: A method of fabricating silicon nitride read only memory. A trapping layer is formed on a substrate. Next, a patterned photoresist layer is formed, and the substrate region at the lower section of the trapping layer masked by the photoresist layer is defined as a channel region. The substrate region at the lower section of the trapping layer and no masked by the photoresist layer is defined as a source/drain region. Next, a pocket ion implantation is performed while using the photoresist layer as amask, and a first dopant is implanted into the source/drain region of the substrate. The photoresist layer is used as a mask and the source/drain ions are implanted. A second dopant is implanted into the source/drain region of the substrate. After that, the photoresist layer is removed.

Abstract: An SOI layer is formed on a silicon substrate with a buried insulating layer therebetween. An SOI-MOSFET is formed including a drain region and a source region that are formed to define a channel formation region at the SOI layer and including a gate electrode layer opposite to the channel formation region with an insulating layer therebetween. An FS isolation structure is formed to have an FS plate opposite to a region of the SOI layer in the vicinity of the edge portion of the drain region and the source region, and to electrically isolate the SOI-MOSFET from other elements by applying a prescribed potential to the FS plate to fix the potential of the region of the SOI layer opposite to the FS plate. The channel formation region includes two edge portions on both sides and a central portion between the edge portions in a direction of a channel width, and a channel length at the edge of a prescribed region is smaller than a channel length at the central portion.

Abstract: In a semiconductor device, a plurality of MIS transistors of the same conductivity type having different thresholds are formed at a main surface of semiconductor substrate, and impurity profiles on section extending in a depth direction from the main surface of the semiconductor substrate through respective channel regions of the plurality of MIS transistors have peaks located at different depths. This structure is formed by ion implantation performed on the respective channel regions with different implanting energies or different ion species. According to this semiconductor device, the thresholds of the MIS transistors can be individually controlled, and transistor characteristics optimum for uses can be obtained.

Abstract: A simple method for fabricating a field-effect transistor having an anti-punch-through implantation region is provided. After the anti-punch-through implantation region is formed, a semiconductor substrate is locally oxidized by using a mask layer in order to form a gate insulation layer. The method allows the fabrication of field-effect transistors having improved short-channel properties.

Abstract: A method for forming a self-aligned local-halo metal-oxide-semiconductor device is provided. The present method is characterized in that a pair of first sidewall spacers is firstly formed on opposite sides of a gate electrode over a semiconductor substrate, and then a pair of second sidewall spacers is formed, each of which formed on one side of each first sidewall spacer. Next, a raised source/drain is formed upward on the substrate between each shallow trench isolation and each second sidewall spacer. Thereafter, the pair of second sidewall spacers is stripped away. Then, the gate electrode and raised source/drain act as the self-aligned ion implant masks, a LDD/Halo implantation is performed to form a local LDD/Halo diffusion region between each shallow trench isolation and each of the first sidewall spacers.

Abstract: A method for making a high voltage insulated gate field-effect transistor with one or more JFET conduction channels comprises successively implanting a dopant of a first conductivity type in a first epitaxial layer of a second conductivity type so as to form a first plurality of buried layers disposed at a different vertical depths. A second epitaxial layer is formed on the first epitaxial layer and the implant process repeated to form a second plurality of buried layers in stacked parallel relationship to the first plurality of buried layers. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. 37 CFR 1.72(b).

Abstract: A high voltage insulated gate field-effect transistor with multiple JFET conduction channels comprises a first buried layer disposed in a first epitaxial layer formed on a substrate, a second buried layer disposed in a second epitaxial layer formed on the first epitaxial layer, with the first and second buried layers being spaced vertically apart in a substantially parallel configuration such that a JFET conduction channel of the first conductivity type is formed between the first and second buried layers. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. 37 CFR 1.72(b).

Abstract: A semiconductor device with a SOI structure comprises; a SOI substrate having a buried insulating film and a first conductivity type surface semiconductor layer on the buried insulating film; second conductivity type source and drain regions formed in the surface semiconductor layer; and a gate electrode formed over a first conductivity type channel region between the source and drain regions via a gate insulating film, wherein the source and drain regions are thinner than the surface semiconductor layer, and the channel region in the surface semiconductor layer has a first conductivity type high-concentration impurity diffusion region whose first conductivity type impurity concentration is higher than that in a surface of the channel region and which is adjacent to the buried insulating film.

Abstract: A method for manufacturing a nonvolatile memory includes steps of forming a first trench of a first width in a substrate of a first conductivity type, forming a second trench within the first trench, having a second width smaller than the first width of the first trench, injecting ions into a surface of the substrate and into sidewalls of the first and second trenches to adjust a threshold voltage, forming first insulating film sidewalls on the sidewalls of the first and second trenches, forming source and drain regions by injecting second conductive impurity ions into the substrate and bottom surfaces of the first and second trenches, depositing a second insulating film on the substrate, forming a floating gate and a gate electrode on sidewalls of the second insulating film within the first and second trenches, depositing a third insulating film on the substrate, and forming a control gate on sidewalls of the third insulating film at a sidewall of the first trench.

Abstract: A method for making a high voltage insulated gate field-effect transistor with multiple JFET conduction channels comprises successively implanting a dopant of a first conductivity type in a first substrate of a second conductivity type so as to form a first plurality of buried layers disposed at a different vertical depths. The first substrate is flipped over and then bonded to a second substrate of the first conductivity type. After the first substrate has been thinned, another set of implants are successively performed so as to form a second plurality of buried layers in stacked parallel relationship to the first plurality of buried layers.

Abstract: For fabricating a field effect transistor on a semiconductor substrate, a gate dielectric of the field effect transistor is formed on a semiconductor substrate. A doped gate electrode, which may be comprised of silicon germanium (SiGe) for example, is formed on the gate dielectric. An amorphous semiconductor structure, which may be comprised of amorphous silicon for example, is formed on the doped gate electrode. A hardmask structure comprised of a hardmask dielectric material is formed on the amorphous semiconductor structure. The gate dielectric, the doped gate electrode, the amorphous semiconductor structure, and the hardmask structure form a gate stack. Liner dielectric structures are formed on sidewalls of the gate stack. A dopant is implanted into exposed regions of the semiconductor substrate after forming the liner dielectric structures on the sidewalls of the gate stack.

Abstract: An inverted MOSFET process. A replacement gate (100) and removable sidewalls (80) allow the formation of spot implant regions (120) and (130) to form the pocket region (120) and the drain and source regions (130) of the MOSFET. The replacement gate (100) has a flared profile for reduced resistance.

Abstract: A semiconductor device exhibiting a super-steep retrograde channel profile to reduce susceptibility to “latch up” is achieved by forming a high impurity concentration layer on a semiconductor substrate and forming a diffusion cap layer near the surface of the high impurity concentration layer. Subsequently, a low impurity concentration layer is formed on the diffusion cap layer of the high impurity concentration layer. The diffusion cap layer formed between the high and low impurity concentration layers substantially prevents the impurities contained in the high impurity concentration layer from diffusing into the overlying low impurity concentration layer, thereby achieving a super-steep retrograde channel profile.

Abstract: A logic circuit having a first logic gate and remaining logic gate or gates. The first logic gate is interposed in a signal path determining an operating speed, and includes at least one first MOS transistor which has a threshold voltage lower than a predetermined voltage and operates at a high speed. The remaining logic gate or gates include at least one of a second MOS transistor and a third MOS transistor as a transistor having a margin for operating speed. The second MOS transistor has a middle threshold voltage equal to or greater than the predetermined voltage, and the third MOS transistor has a high threshold voltage equal to or greater than the predetermined voltage. The power consumption of the entire logic circuit at the time of operation is reduced, while maintaining the maximum operating speed.

Abstract: A system for producing metal gate MOSFETs having relatively low threshold voltages is disclosed, comprising the steps of forming 200 a gate oxide layer on a semiconductor substrate, forming 210 a dummy gate on the substrate, removing 260 the dummy gate after further processing and depositing 270 a lower metallic gate material on said gate oxide; treating 280 the semiconductor device with a reducing gas immediately after deposition of the lower metallic gate material, and depositing 290 an upper gate metal over the lower gate material.

Abstract: Methods of forming field effect transistors and related field effect transistor constructions are described. A masking layer is formed over a semiconductive substrate and an opening having sidewalls is formed therethrough. The opening defines a substrate area over which a field effect transistor gate is to be formed. A dopant of a first conductivity type is provided through the opening and into the substrate. Sidewall spacers are formed over respective sidewalls of the opening. Enhancement dopant of a second conductivity type which is different from the first conductivity type is provided through the opening and into the substrate. A transistor gate is formed within the opening proximate the sidewall spacers, and source drain regions of the second conductivity type are diffused into the substrate operably proximate the transistor gate. The first conductivity type dopant forms a halo region proximate the source/drain regions and lightly doped drain (LDD) regions for the transistor.

Abstract: Short channel effects are curtailed thereby increasing integrated circuit speed by forming a channel dopant with an asymmetric impurity concentration profile. Embodiments include ion implanting Si or Ge at a large tilt angle to amorphize a portion of a designated channel region with a varying degree of amorphization decreasing from the intended drain region to the intended source region, substantially vertically ion implanting channel dopant impurities and annealing. During annealing, diffusion is retarded in areas of increased amorphization, thereby forming an asymmetric impurity concentration gradient across the channel region increasing in the direction of the source region.

Abstract: A method for forming a CMOS transistor gate with a self-aligned channel implant. A semiconductor structure having a first active area is provided. A first insulating layer is formed on the semiconductor structure, and a second insulating layer is formed on the first insulating layer. The second insulating layer is patterned using a poly reverse mask and an etch selective to the first insulating layer to form a first channel implant opening, and the poly reverse mask is removed. A first channel implant mask is formed exposing the first channel implant opening. Impurity ions are implanted through the first channel implant opening to form a first threshold adjust region and a first anti-punchthrough region. A gate layer is formed over the semiconductor structure, and the first gate layer is planarized to form a gate electrode. The second insulating layer is removed, and lightly doped source and drain regions, sidewall spacers and source and drain regions can be formed adjacent the gate electrode.

Abstract: In a method of manufacturing a semiconductor device comprising a semiconductor body 1 which is provided at a surface 2 with a transistor comprising a gate structure 21, a patterned layer 10 is applied defining the area of the gate structure 21. Subsequently, a dielectric layer 18 is applied in such a way, that the thickness of the dielectric layer 18 next to the patterned layer 10 is substantially equally large or larger than the height of the patterned layer 10, which dielectric layer 18 is removed over part of its thickness until the patterned layer 10 is exposed. Then, the patterned layer 10 is subjected to a material removing treatment, thereby forming a recess 19 in the dielectric layer 18, and a contact window 28,29 is provided in the dielectric layer.

Abstract: A transistor structure is provided for ESD protection in an integrated circuit device. A semiconductor substrate has source and drain diffusion regions and respective source and drain wells under the source and drain diffusion regions. A shallow trench isolation formed over the semiconductor substrate and into the semiconductor substrate separates the source and drain diffusion regions and a portion of the source and drain wells. Source and drain contact structures respectively formed on the shallow trench isolation over the source and drain diffusion regions and extend through the shallow trench isolation to contact the source and drain diffusion regions. An ion implantation is performed through the contact openings into the bottoms of the source and drain wells to control the device trigger voltage and position the discharge current far away from the surface, which increases the device ESD performance significantly.

Abstract: In a method of manufacturing a semiconductor device comprising a transistor having a gate insulated from a channel region at a surface of a semiconductor body by a gate dielectric, an active region 4 of a first conductivity type is defined at the surface 2 of the semiconductor body 1, and a patterned layer is applied consisting of refractory material, which patterned layer defines the area of the planned gate to be provided at a later stage of the process and acts as a mask during the formation of a source zone 11 and a drain zone 12 of a second conductivity type in the semiconductor body 1. In a next step, a dielectric layer 14 is provided in a thickness which is sufficiently large to cover the patterned layer, which dielectric layer 14 is removed over part of its thickness by means of a material removing treatment until the patterned layer is exposed, which patterned layer is removed, thereby forming a recess 15 in the dielectric layer 14 at the area of the planned gate.

Abstract: A method of reducing junction capacitance. In a doped substrate or well, a super steep counter-doped implantation is performed, so as to form a super steep counter-doped region beneath the source/drain region in the substrate. As a consequence, the region near the source/drain region has a reduced doping concentration, and the junction capacitance of the source/drain region is reduced.

Abstract: A field effect transistor (300) having a source region (304) and a drain region (306) includes a source side halo region (332) formed at a junction between the source region and a channel region to substantially interrupt off state leakage current. The source side halo region is formed by implanting (408) first doping ions near the surface at the source side of the channel and implanting (410) second doping ions deeper in the channel, near the depth of a source extension (322). In this manner, optimization of leakage current of the field effect transistor is made independent of the drive current of the field effect transistor.

Abstract: The disclosure describes an exemplary embodiment relating to a method of forming halo regions in an integrated circuit. This method includes forming dummy spacer structures over an integrated circuit substrate proximate lateral side walls of a gate structure, providing an oxide layer over the integrated circuit substrate, removing the dummy spacer structures to create windows in the oxide layer exposing the integrated circuit substrate, providing an amorphization implant through the windows to form amorphous regions in the integrated circuit substrate, providing a halo dopant implant through the windows to the amorphous regions, and recrystallizating the amorphous regions in the integrated circuit substrate to form halo regions.

Abstract: A method for manufacturing a nonvolatile memory includes steps of forming a first trench of a first width in a substrate of a first conductivity type, forming a second trench within the first trench, having a second width smaller than the first width of the first trench, injecting ions into a surface of the substrate and into sidewalls of the first and second trenches to adjust a threshold voltage, forming first insulating films sidewalls on the sidewalls of the first and second trenches, forming source and drain regions by injecting second conductive impurity ions into the substrate and bottom surfaces of the first and second trenches, depositing a second insulating film on the substrate, forming a floating gate and a gate electrode on sidewalls of the second insulating film within the first and second trenches, depositing a third insulating film on the substrate, and forming a control gate on sidewalls of the third insulating film at a sidewall of the first trench.

Abstract: A metal-oxide-semiconductor (MOS) device in which the nonuniform dopant concentration in the channel region is obtained by means of ion implantation through a polysilicon gate electrode of nonuniform cross section, which is itself obtained by oxidizing the polysilicon using a semirecessed LOCOS process.

Abstract: A process for manufacturing a semiconductor device includes the formation of tungsten contact plugs suitable for very small geometry devices. As part of the process a tungsten barrier layer is deposited into vias and covering the walls of the vias by a process of ionized metal plasma deposition. The tungsten layer deposited in this manner provides a barrier layer, adhesion layer, and nucleation layer for the subsequent chemical vapor deposition of tungsten contact plug material. Together the two layers of tungsten form contact plugs having a low resistance even when used in the fabrication of very small geometry devices.

Abstract: The invention is related to a method for fabricating a channel region of a transistor device by ion implantation with a large angle and the transistor device formed therefrom. The transistor device is formed on a substrate. Furthermore, the ion implantation with a large angle forms the channel of the transistor in order to prevent the punchthrough phenomenon between the source region and the drain region. In addition, the profile of the channel region is compact and non-uniform. Therefore the ion concentration is higher in the middle of the channel region than in the other regions. Thus, the parasitic capacitance and the junction leakage can be reduced. The carrier mobility is higher than that of the prior art. Moreover, the threshold voltage is more easily controlled than that of the prior art.

Abstract: A dummy gate electrode is formed before the gate electrode is formed. Extension regions, side wall silicon nitride film, source/drain regions, silicon oxide film, and others are formed with respect to the dummy gate electrode. The dummy gate electrode is removed, and a part of the extension regions diffused to a region immediately under the dummy gate electrode is removed. The removed part is filled with silicon selection epitaxial film. Thereafter, the intended gate electrode is formed. This production method gives a semiconductor device that prevents the deterioration of electrical characteristics caused by short channel effect and parasitic resistance.

Abstract: A semiconductor storage unit and a method of manufacturing the same are provided. In the semiconductor storage unit, the formation of a gate electrode within a semiconductor substrate decreases the occurrence of a short circuit between conductive layers, provides an excellent electric connection in a connection hole between the semiconductor substrate and a conductive layers, and also reduces the number of manufacturing processes. In a semiconductor substrate, unit memory cells and are formed by providing a gate electrode in a region where a second opening is formed in a first opening, a first impurity-diffusion layer, a second impurity-diffusion layer, a third impurity-diffusion layer, a bit line, a charge-storage electrode, a capacity insulating film, and a plate electrode. Regions where the second opening is not formed are isolation regions and between memory cells.

Abstract: In a semiconductor device and method for manufacturing the same, a buried insulating layer is formed on a semiconductor substrate, multiple depletion regions of a first conductivity type are formed on the buried insulating layer and separated from one another, a field oxide layer is formed among the depletion regions of the buried insulating layer, a gate oxide layer is formed on the depletion regions, a gate is formed on the gate oxide layer, impurity regions that are heavily doped with impurities of a second conductivity type is formed in the depletion regions on both sides of the gate to define a source and drain, and a counter doping layer that is lightly doped with impurities of the second conductivity type is formed under the channel defined by a portion of the depletion regions positioned between the impurity regions.

Abstract: A high voltage transistor exhibiting high gated diode breakdown voltage, low leakage and low body effect is formed while avoiding an excessive number of costly masking steps. Embodiments include providing a high gated diode breakdown voltage by masking the high voltage junctions from the conventional field implant and masking the source/drain regions from the conventional threshold adjust implant. Angled openings are formed in the field implant blocking mask so that the field implant at varying distances away from the junctions, thus achieving low leakage and a high gated diode breakdown voltage. The field implant blocking mask is extended over the channel area, thereby producing a transistor with low body effect.

Abstract: A method of fabricating a semiconductor transistor device comprising the following steps. A semiconductor structure is provided having an upper silicon layer, a pad dielectric layer over the upper silicon layer, and a well implant within a well region in the upper silicon layer. A lower SiN layer is deposited and patterned over the pad dielectric layer to define a lower gate area. The pad dielectric layer and the upper silicon layer within the lower gate area is etched to form a lower gate trench having a predetermined width. A lower gate portion is formed within the lower gate trench. An upper oxide layer is formed over the lower SiN layer. An upper SiN layer is formed over the upper oxide layer. The upper SiN layer is etched to define an upper gate trench having a predetermined width greater than the lower gate trench predetermined width. An upper gate portion is formed within the upper gate trench, wherein the lower and upper gate portions form a T-shaped gate.