Abstract: Method of fabrication of a no-field transistor with no extra process costs, providing for defining an active area for the transistor surrounded by a thick field oxide layer, insulatively placing a polysilicon gate electrode across the active area to define source/drain regions of the no-field transistor, providing an implant protection mask over a boundary between at least one of the source/drain regions and the field oxide layer, selectively implanting in said source/drain regions a relatively heavy dose of dopants to form relatively heavily doped source/drain regions and to simultaneously dope the polysilicon gate electrode, the polysilicon gate electrode formed with lateral wings extending towards the at least one source/drain region, and the implant protection mask extending over the lateral wings but not over the polysilicon gate.

Abstract: A method for forming field oxide isolation regions using oxygen implantation is described. An oxidation resistant layer such as silicon nitride is formed on a silicon substrate, and acts as an oxidation mask. An opening is then formed in the nitride layer, where field oxide is desired. In one embodiment of the invention, oxygen is implanted into this opening, followed by thermal oxidation. In a second embodiment of the invention, the opening is thermally oxidized, followed by a deep oxygen implant and anneal. Encroachment of the field oxide under the nitride layer is decreased, resulting in a minimum “birds' beak” length.

Abstract: The present invention discloses a method to form CMOS transistors for high speed and lower power applications. A high energy and low dose phosphorous is implanted in a silicon substrate to fabricate an N-well after a pad oxide layer and a silicon nitride layer is formed. After a thick field oxide is formed by using a high temperature steam oxidation process, another high energy and low dose multiple boron implantation is then performed to fabricate a buried heavily boron doped region. A rapid thermal processing (RTP) system is following used to activate the boron dopant to form buried p+ layer and to recover the implanted damages. All the field oxide films are then removed by using a diluted HF or BOE solution. After porous silicon is obtained via anodic electrochemical dissolution in the HF solution, the porous silicon is then thermally oxidized to form the separate n-type silicon islands. Next, a thick CVD oxide film is deposited and then etched back to planarize device surface.

Abstract: A method for forming enhanced field oxide (FOX) region of low voltage devices in a high voltage process is disclosed. The method includes providing a semiconductor structure comprising a substrate, two field oxide regions on the substrate, a well between the two field oxide regions in the substrate and a silicon nitride layer between the two field oxide regions above the well. As a key step, nitrogen is implanted into the semiconductor structure, and the silicon nitride layer is then removed. Then, a gate oxide layer on the well and silicon oxynitride layer on the field oxide regions are all formed in-situ.

Abstract: A process for creating a substrate including bulk silicon regions and semiconductor-on-insulator regions. Regions of a surface of a bulk silicon substrate are recessed above regions where it is desired to create buried oxide regions in the substrate. Implant mask regions are formed on the surface of the substrate over regions where it is not desired to create buried oxide regions. Buried oxide regions are formed in the substrate under the recessed regions in the substrate. The implant mask regions are removed, leaving bulk silicon regions between the buried oxide regions.

Abstract: For use with a sub-micron semiconductor process, a trench isolation process enables the formation of a wider isolation oxide around the shallow trench isolation (STI) opening. The wider oxide width minimizes the recessing of oxide along the trench sidewalls during subsequent cleaning and etching steps. In a method for forming STI regions on a silicon substrate having a buffer oxide thereon and a nitride layer on top of the buffer oxide, a mask layer is defined on the nitride layer patterning isolation regions in unmasked areas of the nitride layer. Isolation regions of sufficient depth are etched through in unmasked areas of the nitride layer, the buffer oxide and into the silicon substrate. Performing a lateral etch (a nitride shaving) of the nitride layer under the mask layer undercuts a portion of the nitride layer under the mask layer. After the lateral etch, the mask layer is removed.

Abstract: On the surface of a field oxide film (3 of FIG. 2e) formed on a substrate region where the effective thickness in the vertical direction of a substrate is diminished due to the presence of a crystal defect (2 of FIG. 1a), the field oxide film is etched by a predetermined thickness until a recess (4 of FIG. 2f) ascribable to the presence of the defect is exposed (step of FIG. 2f). A new oxide film then is formed in an amount corresponding to the above-mentioned thickness on the field oxide film (step of FIG. 3g) to diminish the depth of the recess ascribable to the presence of the defect. To provide a semiconductor device in which leakage between elements can be eliminated with a thin LOCOS oxide film thickness remaining unchanged.

Abstract: The present invention provides an SOI device and its isolation method capable of solving both Well-resistance and punch-through problems. To realize foregoing device, there is provided a semiconductor layer that a region in which a field oxide film having relatively wider width is formed later, is thicker than a region in which a field oxide film having relatively narrower width is formed later. Those field oxide films having different widths with an equal thickness are formed on the field regions of the semiconductor layer. Herein, the thickness of the semiconductor layer below the field oxide film having relatively wider width is thicker than the thickness of the semiconductor layer below the field oxide film having relatively narrower width owing to the fact that the semiconductor layer has various thicknesses according to the respective regions.

Abstract: A method of fabricating a feature on a substrate is disclosed. In a described embodiment the feature is the gate electrode of an MOS transistor. In this embodiment a polysilicon layer is formed on the substrate. Next, an edge definition layer of silicon nitride is formed on the feature layer. Then, a patterned edge definition layer of silicon dioxide is formed on the first edge definition layer. Then, a silicon nitride spacer is formed adjacent to an edge of the patterned second edge definition layer. Finally, the polysilicon layer is etched, forming the transistor gate electrode from the polysilicon that remains under the spacer.

Abstract: A method for forming a photodiode is provided. A substrate having a well with a first electric type therein is provided. An insulating layer is formed on the substrate. The insulating layer is patterned to form an opening. The insulating layer still remains with a thin thickness below the bottom of the opening. A heavily doped region with a second electric type is formed in the well in the position below the opening. A junction is thus formed between the heavily doped region and the well.

Abstract: A method for fabricating a semiconductor integrated circuit having MOS (Metal-Oxide-Semiconductor) transistors which do not produce increased leakage currents upon exposure to radiation and which are free of lateral diffusion of impurities from channel stopper layers. The method comprises the steps of (a) applying ions of an impurity of one conductivity type with a relatively high energy toward a central region of a field oxide film formed as a isolating region in a semiconductor substrate of the same conductivity type as the one conductivity type; and (b) applying ions of the impurity with a relatively low energy toward at least a peripheral region of the field oxide film.

Abstract: A high voltage transistor exhibiting high gated diode breakdown voltage, low leakage and low body effect is forced 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, masking the source/drain regions from the conventional threshold adjust implant, and employing a very lightly doped n-type implant in lieu of conventional n+ and LDD implants. Appropriate openings are formed in the field implant blocking mask so that the field implant occurs at the edges of the junctions, thus achieving low leakage. The field implant blocking mask is extended over the channel area, thereby producing a transistor with low body effect.

Abstract: A trench isolation structure for high voltage device is provided including a high voltage well, a low voltage well, and trench oxide. The high voltage well is formed first to be the deep junction isolation of isolation region. Next, the trench oxide isolation is formed overlying the high voltage well. Then, the low voltage well with higher concentration is formed underlying the trench oxide by using high energy implant. The isolation structure is a trench oxide(dielectric isolation)-junction isolation structure.

Abstract: An integrated circuit memory device includes a semiconductor substrate having a memory cell area and a select transistor area. A first field insulation layer is included in the memory cell area, and a first channel stop impurity layer is included beneath the first field insulation layer. The first channel stop impurity layer is narrower than the first field insulation area. A second field insulation layer is included in the select transistor area, and a second channel stop impurity layer is included beneath the second field insulation layer. The second channel stop impurity layer is wider than the second field insulation layer. Integrated circuit memory devices are fabricated by defining a memory cell area and a select transistor area of a semiconductor substrate. The memory cell area includes a memory cell active area and a memory cell field area. The select transistor area includes a select transistor active area and a select transistor field area.

Abstract: A semiconductor processing method of forming a static random access memory cell having an n-channel access transistor includes, providing a bulk semiconductor substrate; patterning the substrate for definition of field oxide regions and active area regions for the n-channel access transistor; subjecting the patterned substrate to oxidizing conditions to form a pair of field oxide regions and an intervening n-channel access transistor active area therebetween, the field oxide regions having respective bird's beak regions extending into the n-channel access transistor active area, the n-channel access transistor active area defining a central region away from the bird's beak regions; and conducting a p-type V.sub.T ion implant into the n-channel active area using the field oxide bird's beak regions as an implant mask to concentrate the V.sub.T implant in the central region of the active area.

Abstract: CMOS devices and process for fabricating low voltage, high voltage, or both low voltage and high voltage CMOS devices are disclosed. According to the process, p-channel stops and source/drain regions of PMOS devices are implanted into a substrate in a single step. Further, gates for both NMOS and PMOS devices are doped with n-type dopant and NMOS gates are self-aligned.

Abstract: In a Bi-CMOS integrated circuit device, to reduce a collector-substrate junction capacitance in an NPN transistor and to reduce the step of forming an anti-punch-through layer of the N-channel MOS transistor. Using as a mask a resist pattern having windows made on an element isolation LOCOS film 113a, 113c and P-type well layer 106, impurities are ion-implanted to form a channel stopper layer 115a, 115b for element isolation of a NPN transistor and an anti-punch-through layer 115c for a N-channel MOS transistor. Thus, a sufficient element isolation withstand voltage can be assured while avoiding an increase in the collector-substrate capacitance of the NPN transistor which is due to the transverse diffusion of the channel stopper layer when an epitaxial layer, well layer and LOCOS film are formed. In addition, without increasing the number of steps, the drain-source withstand voltage of the N-channel type MOS transistor and the short channel durability can be improved.

Abstract: Disclosed are an isolation film of a semiconductor device and a method for fabricating the same, which prevent the isolation film from being damaged due to misalignment when forming a contact hole in a region adjacent to the isolation film, to ensure stable effective isolation distance. The isolation film of a semiconductor device includes a semiconductor substrate, a lower isolation film formed in the semiconductor substrate, and an upper isolation film formed on the lower isolation film, with a material having etching selectivity different from the lower isolation film.

Abstract: Undesirable birds beak pull back due to ion implant damage is alleviated by additional oxide growth.

Abstract: The present invention relates to a method for fabricating semiconductor devices having triple wells, the present invention has an effect as follows. The present invention provides carrying out N-well and P-well and R-well ion implantation using a mask for implanting two wells after forming an element isolation oxide film, defining an accurate well region by forming wells having an accurate profile due to activating impurity ions in accordance with the thermal process, and improving the punch characteristic between a well and a well.

Abstract: A method and structure for forming a modified field oxide region having increased field oxide threshold voltages (V.sub.th) and/or reduced leakage currents between adjacent device areas is achieved. The method involves forming a field oxide using the conventional local oxidation of silicon (LOCOS) using a patterned silicon nitride layer as a barrier to oxidation. After forming the LOCOS field oxide by thermal oxidation and removing the silicon nitride, a conformal insulating layer composed of silicon oxide is deposited and anisotropically etched back to form sidewall insulating portions over the bird's beak on the edge of the LOCOS field oxide, thereby forming a new modified field oxide. P-channel implants are formed in the device areas. Then a second implant is used to implant through the modified field oxide to provide channel-stop regions with modified profiles that increase the field oxide V.sub.th and/or reduce leakage current between device areas.

Abstract: A method of forming a semiconductor device and the device, the method comprising the steps of providing a silicon substrate of predetermined conductivity type having a layer of silicon oxide with a first mask thereon, implanting a first impurity of the predetermined conductivity type into the substrate in unmasked regions of the substrate, masking the substrate except for a small region immediately adjacent the first mask with a second mask, implanting a second impurity of the predetermined conductivity type into the substrate in the unmasked regions of the substrate to cause some of the impurity to extend in the substrate beneath the first mask, removing the second mask, oxidizing the substrate with the first mask thereon to form a bird's beak extending beneath the first mask with the impurities extending along the bird's beak both beneath and external to the first mask and completing fabrication of a semiconductor device on substrate.

Abstract: A semiconductor device includes a first conductivity type low concentration impurity layer provided around a thick silicon oxide film, which is formed for element isolation in a first conductivity type element region as a surface region in a semiconductor substrate, and a second conductivity type impurity layer which is provided immediately under at least the thick silicon oxide film. The second conductivity type impurity layer constitutes a channel stopper to enhance the effect of element isolation. The first conductivity type low concentration impurity layer has an effect of improving the P-N junction breakdown voltage of an active region in the first conductivity type element region, and suppresses the narrow channel effect of a MOS transistor in the first conductivity type element region.

Abstract: A semiconductor processing method of forming complementary metal oxide semiconductor memory circuitry includes, a) defining a memory array area and a peripheral area on a bulk semiconductor substrate, the peripheral area including a p-well area for formation of NMOS peripheral circuitry, the peripheral area including a first n-well area and a second n-well area for formation of respective PMOS peripheral circuitry, the first and second n-well areas being separate from one another and having respective peripheries; b) providing a patterned masking layer over the substrate relative to the peripheral first and second n-wells, the masking layer including a first masking block overlying the first n-well and a second masking block overlying the second n-well, the first masking block masking a lateral edge of the first n-well periphery; and c) with the first and second masking blocks in place, providing a buried n-type electron collector layer by ion implanting into the bulk substrate; the resultant n-type electron

Abstract: A semiconductor device includes a substrate having an active region between field oxide films, a gate formed on the substrate with a gate oxide therebetween, and a first impurity region formed adjacent to each side of the gate. A second impurity region is formed between the field oxide film and the first impurity region and a first insulating film with a contact hole exposes portions of the first and second impurity regions. An electrode formed in the contact hole such that the portions of the first and second impurity regions overlap an area in the substrate beneath the electrode.

Abstract: A pretreatment system for analyzing impurities contained in a flat sample contains a cylindrical lower case having a stepped portion on which the flat sample is seated. The stepped portion is formed in an circumferential inner surface of the cylindrical lower case. A cylindrical upper case is detachably attached to an upper surface of the lower case, and has a supply passage through which a predetermined amount of pretreatment solution can be supplied to the flat sample. A cover closes off the upper surface of the upper case.

Abstract: Methods of forming EEPROM memory cells having uniformly thick tunnelling oxide layers include the steps of forming a preliminary field oxide isolation region of first thickness at a face of a semiconductor substrate of first conductivity type (e.g., P-type) and then forming a tunneling oxide layer on the face, adjacent the preliminary field oxide isolation region. The memory cell's drain region dopants are then implanted through the preliminary field oxide isolation region and into the substrate to form a preliminary drain region of second conductivity type. The preliminary field oxide isolation region is then grown to a second thickness greater than the first thickness by oxidizing the portion of the substrate containing the implanted dopants, to form a final field oxide isolation region which may have a thickness of about 2000 .ANG..

Abstract: The present invention is a semiconductor device and a method of providing such a semiconductor device which allows a high junction breakdown voltage and a high field turn on voltage, while allowing the field oxide thickness to be limited and being independent of a misalignment of the mask. A method in accordance with the present invention for providing a semiconductor device including a field oxide, the field oxide including a field oxide boundary wherein the field oxide is located within the boundary, the method comprising the step of implanting a first implant area into the substrate, including areas proximate indistance to a junction area, the first area being implanted with a first implant concentration and implanting a second implant area distal to the junction area, the second implant area being implanted with a second implant concentration, wherein the depth of the implant is controlled by the energy level, wherein the implant of the second implant area is independent of a misalignment of a mask.

Abstract: A method for isolating elements in semiconductor devices is disclosed, which includes the steps of: forming a field oxide layer on the surface of a semiconductor substrate; using a photo resist pattern to define a field region and an active region; carrying out an ion implantation of several MeV with the photo resist pattern remaining on the field region, so as to form a channel stop layer on the field oxide layer region; and forming a soft error-preventing buried layer in the active region. The field insulating layer may be a silicon oxide layer or a silicon nitride layer. Additionally, a selective epitaxial process may be carried out so as to raise the level of the active region to substantially the height of the field isolating region, thereby flattening the surface.

Abstract: Methods of forming semiconductor devices containing field oxide and channel-stop isolation regions therein include the steps of forming a plurality of first channel-stop isolation regions by implanting first conductivity type impurities at a first dose level into a face of a semiconductor substrate and then forming respective field oxide isolation regions at the locations where the first channel-stop isolation regions have been implanted. A conductive layer, which contacts active regions of the substrate and covers the field oxide isolation regions, is then patterned over the field oxide isolation regions to expose central portions of the upper surfaces of the field oxide isolation regions.

Abstract: Methods of forming semiconductor active regions having channel-stop regions therein include the steps of forming an oxide layer and first nitride layer on a face of a semiconductor substrate and then patterning the first nitride layer to expose first portions of the oxide layer. The patterned first nitride layer is then used as a mask during implantation of dopants of second conductivity type into the substrate. A second nitride layer is then deposited on the exposed first portions of the oxide layer and on the first nitride layer. A second photoresist layer is then patterned and used as a mask to etch the second nitride layer and patterned first nitride layer, to expose second portions of the oxide layer. A third photoresist layer is then patterned to cover the first portions of the oxide layer. The patterned third photoresist layer and remaining portions of the patterned first and second nitride layers are then used as implant masks during implantation of second conductivity type dopants.

Abstract: A subfield conductive layer is provided, wherein a conductive layer is implanted beneath and laterally adjacent a field dielectric. The subfield conductive layer is placed within the silicon substrate after the field dielectric is formed. The conductive layer represents a buried interconnect which resides between isolated devices. The buried interconnect, however, is formed using high energy ion implant through a field dielectric formed either by LOCOS or shallow trench isolation techniques. The buried interconnect, or conductive layer, resides and electrically connects source and drain regions of two isolated devices.

Abstract: A process for producing integrated circuits including the steps of: selectively growing field insulating regions of insulating material extending partly inside a substrate having a given type of conductivity; depositing a polycrystalline silicon layer on the substrate; shaping the polycrystalline silicon layer through a mask; and selectively implanting ions of the same conductivity type as the substrate, using the shaping mask, through the field insulating regions. The implanted ions penetrate the substrate and form channel stopper regions beneath the field insulating regions.

Abstract: A method for forming semiconductor devices includes a low energy implant for tailoring the electrical characteristics of the semiconductor devices. Using the low energy implant, narrow width devices such as access transistors in an SRAM cell, can be fabricated with a low threshold voltage (Vt). The low energy implant is performed on the active areas of a silicon substrate following field isolation and field implant. For an n-conductivity access transistor, the low energy dopant can be an n-type dopant such as phosphorus, arsenic or antimony.

Abstract: An element separating oxide film is formed in a surface of a p-type silicon substrate for separation of an element forming region. A p-type impurity diffusion region extends from the vicinity of a lower surface of the element separating oxide film to a position at a predetermined depth in the element forming region. The p-type impurity diffusion region has a peak of concentration of impurity. In the element forming region adjacent to the element separating oxide film, an n.sup.+ impurity diffusion region is formed on the surface of the p-type silicon substrate. An n.sup.- impurity diffusion region adjacent to the n.sup.+ impurity diffusion region is formed between the n.sup.+ impurity diffusion region and the p-type impurity diffusion region.

Abstract: A method and system for providing a semiconductor device with device isolation and leakage current control which entails processing a semiconductor substrate to form a semiconductor circuit, and providing at least one high energy implant on the semiconductor circuit is disclosed. The high energy implant is provided at an angle to source and drain regions of the semiconductor circuit so as to allow a dosage from the at least one high energy implant below and away from the surface of the active device region. In so doing, a profile is provided in which dopant distribution is substantially uniform. Therefore, the breakdown characteristics are increased and the junction capacitance of the device is reduced. Accordingly, a device manufactured in accordance with the present invention has significant advantages over devices manufactured in accordance with conventional processes.

Abstract: Implantation of germanium (45) into a PMOS buried channel to permits the enhancement implant profile (to 45) to be made more shallow. The shallow profile will reduce or eventually solve P-channel buried channel-induced short channel effects and enable further decrease in device length to deep submicron range. Benefits include better short channel characteristics, i.e., higher punch through voltage BVDSS, less VT sensitivity to the drain voltage (defined as curl) and better subthreshold leakage characteristics.