Abstract: A semiconductor device having an adjacent P-well and N-well, such as a complementary metal oxide semiconductor (CMOS) transistor, on a silicon on insulator (SOI) substrate has a latch-up problem caused by the parasitic bipolar effect. This invention provides a semiconductor device removing the latch-up problem and methods for fabricating the same. A semiconductor device according to the present invention has a T-shaped field oxide layer connected to a buried oxide layer of the SOI substrate to prevent the latch-up problem.

Abstract: A method of forming local interconnection of a SRAM, including the following steps: First, an NMOS and a PMOS are formed on a P-well and an N-well on a substrate, respectively. An isolation oxide layer is formed and the isolation oxide layer on a node is removed. A thin polysilicon layer is formed and N+ shallow implantation and N+ deep implantation is performed by using a photolithography technique. Also, P+ shallow implantation and P+ deep implantation are performed by using a photolithography technique. After the formation of a low resistance material, the low resistance material and the thin polysilicon layer are together formed.

Abstract: This invention is a processing method for electrically isolating CMOS transistors. The method involves implanting a channel stop dopant into field regions between transistor active regions, self aligning relatively thick silicon dioxide over these field regions and providing thin oxide in the active regions that are self aligned to the field regions. The method does not require any shallow trench isolation (STI), and does not require Local Oxidation of Silicon (LOCOS), thereby resulting in little damage to the silicon.

Abstract: The invention provides an isolation technique using fewer process steps and a double charged implantation step (141) for defining a well region (139) of a CMOS integrated circuit device. The invention provides steps of providing a semiconductor substrate comprising an multiple layer of films (105, 107, 109). These films include an oxide layer (105) overlying the substrate, a polysilicon layer (107) overlying the oxide layer, and a nitride layer (109) overlying the polysilicon layer. The invention also uses a step of removing a first portion of the nitride layer and a first portion of the polysilicon layer defined underlying the first portion of the nitride layer and removing a second portion of the nitride layer and a second portion of the polysilicon layer defined underlying the second portion of the nitride layer. This sequence of steps provides a partially completed semiconductor structure that defines isolation regions before forming well regions for active devices.

Abstract: This invention proposes a process to form planarized twin-wells for CMOS devices. After depositing a pad oxide and a silicon nitride layers, a high-energy phosphorus ion implantation is performed to form the N-well by using a photoresist as s mask. A thick oxide layer deposited by liquid phase deposition process is then grown on the N-well region part of the silicon nitride layer, but not on the photoresist. After stripping the photoresist, a high-energy boron ion implantation is carried out to form the P-well by using the LPD-oxide layer as a mask. The thick LPD-oxide layer is removed by BOE or HF solution. A high temperature steam oxidation is performed to grow field oxides. The dopants are activated and driven in to form twin-wells at this step. After removing the pad oxide and the silicon nitride layer, the CMOS device is fabricated by standard processes.

Abstract: A structure for a complementary field effect transistor includes a semiconductor body having a first body region of a first conductivity type and an adjoining second body region of an opposite second conductivity type. A buried dielectric region is located in the semiconductor body beneath the upper semiconductor surface and extends into the first and second body regions. A first drain region of the second conductivity type is located in the semiconductor body and adjoins the first body region, the dielectric region and the upper semiconductor surface. A second drain region of the first conductivity type is located in the semiconductor body and adjoins the second body region, the dielectric region and the upper semiconductor surface. The two drain regions are adjacent to one another.

Abstract: A method of fabricating a semiconductor device. The procedure of fabricating process is performed inversely as the conventional method. Less numbers of photolithography process is performed with the application of selective liquid phase deposition.

Abstract: A method of establishing a differential threshold voltage during the fabrication of first and second IGFETs having like conductivity type is disclosed. A dopant is introduced into the gate electrode of each transistor of the pair. The dopant is differentially diffused into respective channel regions to provide a differential dopant concentration therebetween, which results in a differential threshold voltage between the two transistors. One embodiment includes introducing a diffusion-retarding material, such as nitrogen, into the first gate electrode before the dopant is diffused into the respective channel regions, and without introducing a significant amount of the diffusion-retarding material into the second gate electrode. Advantageously, a single dopant implant can provide both threshold voltage values. The two threshold voltages may be chosen to provide various combinations of enhancement mode and depletion mode IGFETs.

Abstract: A method forms, in a CMOS semiconductor substrate, P- and N-wells having independently optimized field regions and active regions. In one embodiment, P- and N-wells are formed by (i) creating in successive steps the field regions of the P- and N-wells; (ii) creating an oxide layer over the field regions, (iii) creating in successive steps the active regions. The method achieves the P- and N-wells without increasing the number of photoresist masking steps. In addition, optical alignment targets (OATs) are optionally formed simultaneously with these P- and N-wells without increasing the total number of process steps.

Abstract: A gate oxide and a first conducting layer are formed on a substrate, and then the first conducting layer is patterned and a gate in a NMOS region is formed. A LDD, a sidewall spacer, and a drain/source in the NMOS region are then formed in series. A layer of hard mask is formed. The layer of hard mask and the first conducting layer are patterned and a gate in a PMOS region is formed. A LDD, a sidewall spacer, and a drain/source in the NMOS region are then formed in series.

Abstract: A method of making an IGFET with a selectively doped multilevel polysilicon gate that includes upper and lower polysilicon gate levels is disclosed.

Abstract: In the production of a dual work function CMOS circuit, a polysilicon layer is produced for the purpose of forming a gate structure, the average grain diameter of which polysilicon layer is greater than the minimum extent in the gate structure, in order to suppress lateral dopant diffusion. In particular, a constriction having a width less than the average grain diameter is produced in the gate structure.

Abstract: In order to produce an integrated CMOS circuit, a dielectric layer and a silicon layer are applied to a substrate. During the formation of insulation structurers which insulate neighboring active regions in the substrate, the silicon layer is structured in such a way that it has separate sub-regions which are subsequently doped differently. By full-surface deposition of an electrically conductive layer and common structuring of the electrically conductive layer and the structured silicon layer differently doped gate electrodes and a metallization plane, by which the gate electrodes are electrically connected, are formed. Division of the silicon layer before doping prevents lateral dopant diffusion.

Abstract: The preferred embodiment of the present invention overcomes the limitations of the prior art and provides a device and method to increase the latch-up immunity of CMOS devices by forming implants at the well edges. The preferred method uses hybrid resist to form these implants at the edges of the N-wells and/or P-wells. The implants reduce the lifetime of minority carriers in the parasitic transistor, and hence reduce the gain of the parasitic transistor. This reduces the propensity of the CMOS device to latch-up. The preferred embodiment method allows these implants to be formed without requiring additional masking steps over prior art methods. Furthermore, the preferred method for forming the implants results in implants that are self aligned to the edges of the wells.

Abstract: An integrated circuit is formed with minimal encroachment of lightly doped drain (LDD) implants partially due to barrier atoms incorporated along the migration avenues. Nitrogen is incorporated either during the LDD implant or during an anneal cycle following the LDD implant. Nitrogen helps minimize segregation and diffusion of LDD dopants placed adjacent critical channel and gate dielectric areas. Nitrogen is incorporated within a chamber while under pressure so as to minimize the temperature needed to repair implant damage and activate the LDD dopants. High pressure indoctrination of nitrogen is believed to provide the same amount of lattice repair and activation achieved if anneal temperatures were substantially higher.

Abstract: SRAMs conventionally formed on N-type substrates are instead formed on P-type substrates which have had the surface layer of the substrate converted to a blanket N-type well region. Preferably, the blanket N-type well region is formed by ion implantation of phosphorus ions to a dosage of between 5.times.10.sup.12 to 2.times.10.sup.13 /cm.sup.2 at an energy of 200-1000 KeV. Use of a P-type substrate having a blanket N-well region formed by ion implantation are less expensive than the N-type substrates conventionally used, and make the SRAM processing techniques compatible with the P-type substrates conventionally used in microprocessors and other logic devices.

Abstract: A CMOS process with inverse-T gate LDD structure uses liquid phase deposition (LPD) processes to achieve a low thermal budget with only six photoresist-masks in a CMOS device. A first photoresist-mask is used to form field oxide regions. A second photoresist-mask is used to implant a P-well. Before the second photoresist-mask is removed, a first LPD oxide layer is used to cover the N-well. The second photoresist-mask is removed, and the first LPD oxide layer is used as a mask for implanting the N-well. The first LPD oxide layer is removed and a polysilicon layer is deposited on the substrate. A third photoresist-mask is used to etch the polysilicon layer to form gate-structures for the NMOS and PMOS devices. A conformal amorphous Si layer is formed on the gate-structures, followed by forming a fourth photoresist-mask over the N-well. A conformal LPD oxide layer is formed on the conformal polysilicon layer over the P-well. N-LDD regions are then implanted.

Abstract: A substrate has defined therein one or more active regions. A layer of polysilicon is deposited and patterned to form gates for various CMOS devices. A masking layer is then deposited and selectively etched to leave exposed portions of the substrate. Dopants of a first conductivity type are implanted into the exposed portions of the substrate to form one or more well regions of the first conductivity type. Using this masking layer and the polysilicon gates left exposed thereby as a mask, dopants of a second conductivity type are then implanted into the substrate to form source and drain regions of the second conductivity type in the well regions of the first conductivity type. The masking layer is then removed. In this manner, source and drain regions may be formed using the same masking layer used to define the well within which the source and drain regions lie, thereby reducing both time and expense in the fabrication of CMOS devices.

Abstract: A complementary semiconductor device which includes: a semiconductor substrate having a principal surface, with a first region doped with an impurity of a first conductivity type and a second region doped with an impurity of a second conductivity type; a first MOS transistor provided on the second region; and a second MOS transistor provided on the first region. In such a complementary semiconductor device, at least one of the first MOS transistor and the second MOS transistor is an asymmetric MOS transistor of the same conductivity type as the conductivity type of the corresponding region which is either the first region or the second region.

Abstract: The present invention relates to a high voltage transistor of a semiconductor memory device, and more particularly to a high voltage transistor which improves element isolation and breakdown voltage characteristics thereof.

Abstract: A method of forming an integrated circuit device, and in particular a CMOS integrated circuit device, having an improved lightly doped drain region. The methods include the steps of providing a semiconductor substrate with a P type well region and an N type well region. Gate electrodes are formed overlying gate dielectric over each P type well and N type well regions. The present LDD fabrication methods then provide a relatively consistent and easy method to fabricate CMOS LDD regions with N type and P type implants at a combination of different dosages and angles using first and second sidewall spacers, with less masking steps and improved device performance.

Abstract: A metal-oxide-semiconductor field effect transistor (MOSFET) with reduced leakage current includes drain and source regions separated by a channel, a drain terminal over a portion of the drain region, a source terminal over a portion of the source region and a gate terminal opposite the channel. An oxide layer is deposited over the remaining portions of the drain and source regions, as well as on the adjacent vertical sides and top edges of the drain, source and gate terminals. A silicide layer is deposited over the gate terminal between the oxide-covered top edges thereof and over the drain and source terminal up to the oxide-covered top edges thereof. With oxide over the drain source regions instead of silicide, parasitic Schottky diodes are avoided, thereby eliminating leakage current due to such parasitic elements.

Abstract: A method for manufacturing a semiconductor device, the method includes the steps of forming an n-type well and a p-type well under a surface of a semiconductor substrate, forming a pad oxide layer having a first thickness on the p-type well and a second thickness on the n-type well, the first thickness being greater than the second thickness, and forming a field oxide layer between the n-type well and the p-type well, the field oxide layer having less bird's beak on the n-type well than on the p-type well.

Abstract: A method of manufacturing a semiconductor device comprises; forming a device isolation region in a semiconductor substrate; forming at least a first conductivity type impurity region in the semiconductor substrate; and forming on the semiconductor substrate a transistor including a gate insulating film, a gate electrode, source/drain regions and a channel located directly under the gate electrode, wherein the first conductivity type impurity region is formed by the steps of: an ion implantation 1 having a concentration peak at a location deeper than the bottom of the device isolation region; an ion implantation 2 having a concentration peak at a location around the bottom of the device isolation region; an ion implantation 3 having a concentration peak around the junction regions where the source/drain regions are to be formed; and an ion implantation 4 having a concentration peak on the surface or directly under the surface of the region where the channel is to be formed.

Abstract: This invention discloses a method of manufacturing a semiconductor device, especially a method of forming field isolation, in which a portion of an active region around a field oxide film is highly-doped with the same type impurities as channel-stop impurity ions so that it changes a low-doped channel-stop region which results from a high temperature of field oxidation to a high-doped channel-stop region to prevent field inversion in device operation.

Abstract: A method of fabricating an integrated circuit in which nitrogen is incorporated into the gate dielectric and transistor gate. The method comprises the providing of a semiconductor substrate that has a p-well and a laterally displaced n-well, each including a channel region laterally displaced between a pair of source/drain regions. Preferably, the semiconductor substrate has a resistivity of approximately 10 to 15 .OMEGA.-cm. A dielectric layer is formed on an upper surface of the semiconductor substrate. The formation of the dielectric layer preferably comprises a thermal oxidation performed at a temperature of approximately 600.degree. to 900.degree. C. and the resulting thermal oxide has a thickness less than approximately 50 angstroms. A conductive gate layer is then formed on the dielectric layer. In a preferred embodiment, the conductive gate layer is formed by chemically vapor depositing polysilicon at a pressure of less than approximately 2 torrs at a temperature in the range of approximately 500.

Abstract: A method of fabricating alignment marks on an integrated circuit device including steps of: forming first pad oxide layer and first nitride layer on a P-type semiconductor substrate; coating and patterning first photoresist layer by lithography; partially etching first nitride layer to form first nitride pattern by first photoresist etching mask; and ion implanting N-type ions to form an N-doped region; coating and patterning second photoresist layer by lithography; partially etching first nitride pattern to form second nitride pattern; and ion implanting P-type ions to formed a P-doped region. Next, performing thermally drive in N-type and P-type impurities to form N-well and P-well regions, and growing an oxide layer simultaneously. Finally, the height difference between the oxide layer and the second nitride pattern producing a ladder topography can be used as an alignment mark for the succeeding lithographic processes.

Abstract: The present invention develops a process for forming dual conductive wells in a silicon substrate for an integrated circuit by: forming an oxide layer on the silicon substrate; patterning an oxidation barrier layer on the oxide layer, thereby defining active areas for active devices; introducing first p-type conductive impurities into the silicon substrate thereby forming at least one p-type conductively doped well region; masking over the p-type conductively doped well region; introducing n-type conductive impurities into the silicon substrate thereby forming at least one n-type conductively doped well region; removing the masking; forming oxide regions in areas not covered by the patterned oxidation barrier layer; and forcing the p-type and n-type conductive impurities further into the silicon substrate thereby forming the dual well regions, the well regions having adequate conductive depth to provide for the formation of the active devices.

Abstract: A method of forming first and second conductivity type wells in a semiconductor device includes the steps of forming an isolation layer on a semiconductor substrate, forming a multi-layer mask over a portion of the substrate to define the first and second conductivity type wells, implanting a first conductivity type impurity to form the first conductivity type well, removing a partial layer from the multi-layer mask, and implanting a second conductivity type impurity to form the second conductivity type well.

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 process for fabricating a CMOS structure using a single masking step to define lightly-doped source and drain regions for both N- and P-channel devices. The process forms disposable spacers adjacent to gate structures and at least one retrograde well. Retrograde wells are formed using one or more charged ions at different energy levels. In addition, heavily-doped source and drain regions are formed using blanket implants of two different conductivities into a semiconductor substrate having two contiguous wells of opposite conductivity type. By blanket implanting a first dopant into both wells, and then selectively implanting a second dopant, the diffusion of the second dopant is partially suppressed by the first dopant. The partial suppression of first dopant results in shallow implants being formed. Also disclosed is a process for forming contact openings and contact implants.

Abstract: Region forming steps or interconnect-forming steps through which low voltage CMOS devices are formed in a semiconductor wafer are also employed to simultaneously form one or more regions or layers at selected sites of a substrate where high voltage devices are to be formed. Such selective modification of an already existing mask set designed for low voltage CMOS typography allows additional doping of the substrate or provision of further overlay material to accommodate the effects of high voltage operation of selected areas of the water and thereby effectively performs precursor tailoring or modification of those portions of the wafer where a high voltage condition will be encountered.

Abstract: A process is disclosed for fabricating a CMOS structure with ESD protection. The outside transistors are covered with a protective oxide layer which is so masked as to cover the areas of the respective source and drain regions adjoining the field-oxide regions and the gate regions. The protective oxide layer is then subjected to a heat treatment, after which a siliciding process is carried out.