Abstract: A logic test having less over-head for testing a logic circuit in a chip is implemented by constituting a test circuit in the chip without introducing a novel device process of FPGA. A memory of a self-configuration type is provided in the chip and a test circuit is constituted in the memory of a self-configuration type or an ordinary memory through a tester HDL, thereby testing other memories and logic circuits in the chip. The test circuit is reconstituted such that the memory used in the structure of the test circuit can be operated as an ordinary memory.

Abstract: A read-only memory cell array has vertical MOS transistors formed on trench walls, and is programmed with a programming mask which covers only the areas at which a transistor is not to be produced. As a result, the word lines can be formed with minimum grid spacing and the risk of short-circuiting between adjacent word lines is eliminated by buried ploy stringers.

Abstract: A method for making a ULSI MOSFET chip includes forming a sacrificial gate on a substrate along with activated source and drain regions, but without initially establishing a doped channel region. The polysilicon portion of the sacrificial gate is then removed and a neutral ion species such as Silicon or Germanium is implanted between the source and drain regions in the region that is to become the doped channel region. A dopant substance is next implanted into the channel region, which is then exposed to ultra-rapid thermal annealing to cause the dopant to form a box-like, super-steep retrograded channel profile. The gate is then re-formed over the now activated doped channel region.

Abstract: After completion of wiring strips on an inter-level insulating structure, a field effect transistor is checked to see whether or not the threshold voltage falls within a design range, if the threshold voltage is out of the design range, hydrogen ion is implanted through the inter-level insulating structure, the gate electrode and the gate insulating layer into the channel region of the field effect transistor, and the resultant semiconductor structure is annealed at 400 degrees in centigrade for 20 minutes so as to partially deactivate the dopant impurity in the channel region.

Abstract: A semiconductor device with improved short channel characteristics is formed with a buried amorphous region comprising a retrograde impurity region having the impurity concentration peak of the semiconductor substrate. The buried amorphous region, formed below the channel region, suppresses diffusion of displaced atoms and holes from the source/drain regions and reduces the resistance against latch-up phenomenon, thereby improving short channel characteristics.

Abstract: An integrated circuit and method of fabrication is provided for an integrated circuit having punch-through suppression. Unlike conventional methods of punch-through suppression wherein a dopant implant is fabricated in the device, the present invention utilizes an inert ion implantation process whereby inert ions are implanted through a fabricated gate structure on the semiconductor substrate to form a region of inert ion implant between source and drain regions of a device on the integrated circuit. This accumulation region prevents punch-through between source and drain regions of the device. In a second embodiment, the inert ion implantation is used in conjunction with the conventional punch-through dopant implant. In this second embodiment, diffusion of the implant during subsequent thermal annealing is suppressed by the inert ion accumulation in the subsurface region of the device.

Abstract: A process of forming silicide at uniform rates across the entire source/drain region is provided. A two-step annealing method permits the thickness of the silicide formed on the edge of a silicon electrode to be substantially the same as it is in the center of the electrode. A first, low temperature anneal begins the salicidation process across the source/drain electrode surface. The time and temperature are controlled so that the metal is only partially consumed. The annealing is interrupted to remove excess silicidation metal, especially the unreacted metal overlying oxide areas neighboring the silicon electrode. Then, the silicidation is completed at a higher temperature anneal. Because the excess metal has been removed, the resulting silicide layer is uniformly flat, permitting the transistor to be fabricated with shallow junction areas and low leakage currents.

Abstract: A method for making a ULSI MOSFET chip includes forming a sacrificial gate on a substrate along with activated source and drain regions, but without initially establishing a doped channel region. The polysilicon portion of the sacrificial gate is then removed and a neutral ion species such as Silicon or Germanium is implanted between the source and drain regions in the region that is to become the doped channel region. A dopant substance is next implanted into the channel region, which is then exposed to ultra-rapid thermal annealing to cause the dopant to form a box-like, super-steep retrograded channel profile. The gate is then re-formed over the now activated doped channel region.

Abstract: A method of for fabrication a metal oxide semiconductor transistor is described. A substrate with an isolation structure thereon is provided. A gate oxide layer is formed on the substrate. A polysilicon layer is formed on the gate oxide layer. The polysilicon layer is patterned to form a gate on the gate oxide layer. An offset spacer is formed on the sidewall of the gate. A source/drain extension is formed in the substrate on two sides of the gate by ion implantation. An insulating spacer is formed on the sidewall of the offset spacer. A source/drain region is formed in the substrate by ion implantation using the gate, the offset spacer and the insulating spacer as a mask. Salicide is formed on the gate and on the surface of the source/drain region. After forming the salicide, the offset spacer is removed. After removing the offset spacer, a halo doped region is formed in the substrate below the source/drain extension by ion implantation.

Abstract: Channel doping is implemented such that dopants remain localized under the gate without migrating under the source/drain juctions during processing, thereby avoiding performance degradation of the finished device. Embodiments include implanting impurities at an acute angle to form a lateral channel implant localized below the gate after activation of source/drain regions, and activating the lateral channel implant by a low-temperature RTA during subsequent metal silicide formation. The use of a low-temperature RTA for electrical activation of the lateral channel implant avoids impurity migration under the source/drain junctions, thereby lowering parasitic junction capacitance and enabling the manufacture of semiconductor devices exhibiting higher circuit speeds with improved threshold voltage control.

Abstract: The channel doping profile of a PMOS field effect transistor consists of a shallow distribution of a P-type dopant as a threshold adjust implant, a deeper distribution of an N-type dopant as an buried channel stop implant and a still deeper implantation of an N-type dopant as an antipunchthrough implant. A junction is formed between the P-type threshold adjust implant and the N-type buried channel stop implant at a relatively shallow depth so that the depth of the buried channel region is limited by the buried channel stop implant, reducing the short channel effect. The channel doping profile is formed so that diffsion of impurities from the channel region to the gate oxide is prevented. The buried channel stop implant is made first through a sacrificial oxide layer. The sacrificial oxide is etched and a gate oxide layer and a thin film of polysilicon are deposited on the surface of the gate oxide.

Abstract: A process is described for forming a buried, or pocket, ion implant in a semiconductor device. In particular, said pocket is limited to only the drain side of a field effect transistor. To achieve this the photoresist that is used to protect the source and drain regions during ion implantation is located at different distances from the gate pedestal. The photoresist on the source side is placed closer to the gate pedestal than it is on the drain side. As a result, when ions arrive at the surface at a sufficiently shallow angle to be able to penetrate the semiconductor regions immediately beneath the gate oxide, photoresist at the source side blocks the beam while the photoresist on the drain side is far enough away from the gate not to intercept the beam. Thus, a single asymmetrically located pocket is formed in a single step.

Abstract: A semiconductor nonvolatile storage that is an inter-gate insulating film breakdown type memory is configured by providing a field oxide film on a semiconductor substrate 1, a gate electrode on the field oxide film and a mask oxide film on the surface of the gate electrode, forming an opening m the mask oxide film and forming a memory oxide film on the gate electrode exposed thereat, providing a memory gate electrode of a size extending from over the memory oxide film to over the mask oxide film, and making the thickness of the memory oxide film thinner than the thickness of the mask oxide film.

Abstract: A structural enhancement to a conventional DMOS process flow addresses the well-known destructive latch up problem. The additional steps include a symmetric "deep" punch-through stopper implant and additional thermal budget to remove silicon damage and distribute the ionized dopants appropriately. The purpose of the implant is to create a low resistance base region within the parasitic bipolar transistor to prevent the device from activating under high current conditions. In terms of circuit characteristics, the goal is to lower the voltage drop at node Vx in FIG. 1C during avalanche breakdown. This structure also provides a means of suppressing the phenomena of punch-through breakdown which can also lower the device's voltage reading.

Abstract: A process for forming implanted regions at an optimal location in a semiconductor substrate underneath a patterned polysilicon gate of an MOS transistor. The process includes steps of first providing a semiconductor substrate (e.g. a silicon wafer) with a gate oxide layer on its surface, followed by the formation of a polysilicon gate layer on the gate oxide layer. An additional oxide layer is subsequently formed on the polysilicon gate layer. The resulting structure is then patterned to form a patterned additional oxide layer and a patterned polysilicon gate layer, all of which are subsequently covered by a conformal silicon nitride layer. Next, the conformal silicon nitride layer is anisotropically etched to form spacers on the sidewalls of the patterned structure.

Abstract: There is provided a MOS device with self-compensating threshold implant regions and a method of manufacturing the same which includes a semiconductor substrate, a partial first threshold implant forming a higher concentration layer, a gate oxide formed on the surface of the higher concentration layer, and a gate formed on a surface of the gate oxide. The MOS device further includes a second threshold implant for forming self-compensating implant regions in the substrate which is subsequently heated to define pockets. A third implant is performed to create lightly-doped source/drain regions. A sidewall spacer is formed on each side of the gate. A fourth implant is performed to create highly-doped source/drain regions between the lightly-doped source/drain regions and the pockets.

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: Methods of fabrication of a lateral RF MOS device having a non-diffusion connection between source and substrate are disclosed. In one embodiment, the lateral RF MOS device has an interdigitated silicided gate structure. In another embodiment, the lateral RF MOS device has a quasi-mesh silicided gate structure. Both sides of each gate are oxidized thus preventing possible shorts between source and gate regions and between drain and gate regions. The top of each gate is silicided once the protective layer of silicon nitride is removed.

Abstract: A method of manufacture for a multiple stage ROM unit capable of coding the multiple stages with a single coding implantation and a method of manufacturing the same.The ROM includes a semiconductor substrate covered by an insulating layer. A gate structure is provided above the insulating layer. A channel region is located on the substrate beneath the gate structure. Source/drain regions are disposed on the semiconductor substrate on each side of the channel region. A cap partially covers the top of the gate structure so as to divide the channel region therebelow into a first channel region and a second channel region such that multiple-level threshold voltages may be coded in the ROM.

Abstract: A method of fabricating a semiconductor device and the device. There is provided a substrate (21) of semiconductor material. A gate electrode (25) is formed over the substrate (21) having a sidewall (27) and electrically isolated from the substrate. Source/drain regions (29, 31) are formed in the substrate defining a channel in the substrate extending beneath the gate electrode. One of a pocket region or a halo region (33) extending substantially entirely under the gate electrode and sidewall is then formed. The pocket region or halo region is formed by providing a compensating species which is implanted at the time of the source/drain implant in order to compensate the doping increase under the source/drain caused by the pocket or halo implant. Since the implant dose and range of this compensating implant is comparable to the pocket or halo implant, no penetration of the gate electrode should occur.

Abstract: Sharply-defined dopant profiles in the transistor channel region of ultra high density semiconductor devices are maintained by selective transistor channel implants to reduce exposure to heat cycling, thereby reducing dopant diffusion. Embodiments include forming isolation regions on a semiconductor substrate, forming a relatively thick first gate dielectric layer, then performing transistor channel implantations. The first gate dielectric layer is then masked and etched, and a second, thinner gate dielectric layer is formed. The transistor channel implants are not affected by the temperature cycle of the first gate dielectric layer formation, thereby enabling dual gate dielectric formation without adversely affecting the electrical characteristics of the finished device.

Abstract: A method of making an IGFET with a selectively doped channel region is disclosed. The method includes providing a semiconductor substrate with a device region, forming a gate over the device region, forming a masking layer that partially covers the gate and the device region, implanting a dopant into portions of the gate and the device region outside the gate that are not covered by the masking layer, transferring the dopant through the uncovered portion of the gate into a portion of an underlying channel region in the device region, thereby providing the channel region with a non-uniform lateral doping profile and adjusting a threshold voltage, and forming a source and a drain in the device region. The dopant can be implanted through the portion of the gate into the portion of the channel region, or alternatively, the dopant can be diffused from the portion of the gate into the portion of the channel region.

Abstract: A method (50) for designing a semiconductor device (10). The method (50) has an annealing step (59). In the annealing step (59), the semiconductor device (10) is annealed in an ambient containing oxygen. The oxygen has a partial pressure of greater than 11.85 Torr. The annealing step (59) results in a reduction of uncontrolled doping from the gate electrode (33) of the semiconductor device (10) to the channel region of the semiconductor device (10).

Abstract: A method of making a lightly doped drain transistor includes the steps of forming a gate electrode (52) and a gate oxide (54) over a semiconductor substrate (56) and forming a drain (70) in a drain region (58) and a source (72) in a source region (60) of the substrate (56). The method further includes generating interstitials (62) near a lateral edge of at least one of the drain (70) and the source (72) and thermally treating the substrate (56). The thermal treatment cause the interstitials (62) to enhance a lateral diffusion (84) of the drain (70) under the gate oxide (54) without substantially impacting a vertical diffusion (82) of the drain (70) or the source (72). The enhanced lateral diffusion (84) results in the formation of at least one of a lightly doped drain extension region (75) and a lightly doped source extension region (76) without an increase in a junction depth of the drain (70) or the source (72).

Abstract: A method of manufacturing a semiconductor device with a steep retrograde profile. The threshold voltage adjust dopant layer and the punchthrough prevent dopant layer are formed in the substrate. All surface capping layers are removed from the active device regions and, the semiconductor device is placed in a chamber and a high vacuum is established after which an inert atmosphere is introduced into the chamber. The anneal to repair the damage to the lattice and to activate the dopant ions in the dopant layers is done in the inert atmosphere with the surface of the substrate maintained clean, that is, free from a capping oxide or other layer formed on the surface of the substrate.

Abstract: A process for fabricating a memory cell having two levels of polysilicon and being included in a memory device of the EEPROM type, wherein the device is formed on a semiconductor material substrate which has a first conductivity type. The process comprises the steps of forming, on the substrate a thin tunnel oxide region surrounded by a gate oxide region previously formed on the same substrate, depositing a layer of polycrystalline silicon over the gate oxide region and the thin tunnel oxide region, and successively depositing a composite ONO layer and an additional polysilicon layer over the polycrystalline silicon layer.

Abstract: A method of forming a transistor includes forming a gate dielectric layer upon a substrate, forming a polysilicon layer upon the gate dielectric layer and then forming a thin nitride layer upon the gate polysilicon layer. The thin nitride layer is then pattern etched to define a nitride cap above a future channel. The gate polysilicon layer and a portion of the silicon substrate below the gate dielectric layer is then doped with arsenic. An optional annealing step then causes some of the arsenic to migrate below the nitride cap. A subsequent oxidation step then causes gate conductor/gate oxide stacks with integrated spacers to be defined below the nitride cap. The oxidation step and optional prior annealing step also cause some arsenic to migrate into the channel to form the LDD regions. The substrate is etched to remove portions of the gate polysilicon layer unprotected by the nitride cap.

Abstract: A method of reducing an effective channel length of a lightly doped drain transistor (50), includes the steps of forming a gate electrode (52) and a gate oxide (54) over a semiconductor substrate (56) and implanting a drain region (58) of the substrate (56) with a sub-amorphous large tilt angle implant to thereby supply interstitials (62) at a location under the gate oxide (54). The method also includes forming a lightly doped drain extension region (66) in the drain region (58) of the substrate (56) and forming a drain (70) in the drain region (58) and forming a source extension region (67) and a source (72) in a source region (60) of the substrate (56).

Abstract: After a field oxide film is formed on a P-type semiconductor substrate, ion implantation of boron is carried out with respect to a whole surface of the substrate so that a channel stopper layer is formed. Then, a MOS FET is formed in an active region of the semiconductor substrate. Subsequently, ion implantation of phosphorus is carried out, by using a gate electrode of the MOS FET and the field oxide film as a mask, so that impurity layers which have the same type of conductivity as that of the channel stopper layer and has a concentration lower than that of the channel stopper layer are formed right under the source/drain regions of the MOS FET between the source/drain regions and the channel stopper layer.

Abstract: The present invention advantageously provides a method for forming a transistor in which silicide contact areas are formed to the junctions during fabrication of the transistor. The silicide contact areas may be formed using a single high temperature anneal since silicide forming near sidewalls of the gate oxide is prevented. In one embodiment, dopants are first forwarded into a lateral region of a silicon-based substrate to form an implant region. Then a silicide layer is formed across the implant region using a high temperature anneal. A sacrificial material is deposited across the silicide layer and the substrate. A contiguous opening is formed vertically through the sacrificial material and the silicide layer, exposing a portion of the substrate. Dopants of the type opposite to the dopants implanted previously are then implanted into the exposed substrate region to form a channel. Thus, the implant region is separated into source and drain regions having a channel interposed between them.

Abstract: A narrow gate FET is formed on a substrate by providing a first layer of polysilicon on the active device regions of the substrate and doping the polysilicon by ion implantation. An etch/polish stop layer of silicon oxide and is deposited on the first layer of polysilicon. Openings are formed in the etch/polish stop layer and the first polysilicon layer to expose the surface of the substrate. An anneal is performed to diffuse N-type impurities from the first layer of polysilicon into the substrate. The heavily doped portions of LDD source/drain regions are formed partially within the substrate and partially within portions of the first layer of polysilicon left on the surface of the substrate. Next, a first implantation of N-type impurities is made across the opening in the first layer of polysilicon. A layer of silicon nitride is deposited over the first layer of polysilicon and within the openings in the first polysilicon layer.

Abstract: Reverse short-channel effect is suppressed in a field effect transistor with a gate having a short length. The field effect transistor comprises a p-type silicon substrate, a gate electrode, paired lightly doped source/drain regions, and paired heavily doped source/drain regions. A boron concentration peak region is formed in the silicon substrate. A boron concentration peak region positioned at an end of the gate electrode has a length d of one fourth of a length L of the gate electrode, and extends from the end to the center of the gate electrode.

Abstract: A method of forming a short channel field effect transistor is disclosed. The method includes the steps of providing a semiconductor substrate having a well region of a first conductivity type; forming a gate electrode on the well region; implanting first impurities into the well region and adjacent to the gate electrode, the first implant step being at a first dose and a second conductivity type; forming sidewall spacers on edges of the gate electrode; implanting second impurities into the well region and adjacent to the gate electrode, the second implant step being at a second dose and at the second conductivity type; and implanting third impurities into the well region and adjacent the gate electrode, the third implant step being at a third dose and at the first conductivity type.

Abstract: A method of forming a MOS transistor without a lightly doped drain (LDD) region between the channel region and drain is provided. The channel region is formed from a tilted ion implantation after the deposition of the gate oxide layer. The tilted implantation forms a relatively short channel length, with respect to the length of the gate electrode. The position of the channel is offset, and directly adjoins the source. The non-channel area under the gate, adjacent the drain, replaces the LDD region between the channel and the drain. This drain extension acts to more evenly distribute electric fields so that large breakdown voltages are possible. The small channel length, and eliminated LDD region adjacent the source, act to reduce resistance between the source and drain. In this manner, larger I.sub.d currents and faster switching speeds are obtained. A MOS transistor having a short, offset channel and drain extension is also provided.

Abstract: A channel region formation process in field effect transistors directed toward reducing threshold voltage sensitivity to variations in gate length resulting from manufacturing techniques. A polysilicon gate is formed over the substrate and a channel region is subsequently implanted at a large angle measured from perpendicular to the substrate. Large angle implantation results in a non-uniform doping concentration in the channel region, improving threshold voltage sensitivity. Improvement can also be seen in other parameters, including source-drain current, substrate current, leakage current, magnification factor, and hot electron channel injection efficiency.

Abstract: A gate oxide layer and a polysilicon layer are formed in sequence over the major surface of a semiconductor substrate. A photoresist layer is formed on the polysilicon layer and an opening is formed in the photoresist layer. Using the photoresist layer as a mask, boron is ion implanted through the polysilicon layer and the gate oxide layer into the semiconductor substrate. Phosphorus is next ion implanted into the polysilicon layer by using the photoresist layer as a mask. Different ion species are ion implanted into the semiconductor substrate and the polysilicon layer, respectively, by using the same photoresist layer, thus decreasing the number of photoetching steps in manufacture of semiconductor devices.

Abstract: A manufacturing method of high voltage MOSFET includes a process forming the first and second conductive wells in a semiconductor substrate; process forming drift areas in the first and second conductive wells; process growing an isolation membrane on the substrate surface between the first and second conductive wells; process forming a gate insulation film; process forming a gate on the gate insulation film above the first and second conductive wells; process forming low concentration n- and p-type dopant areas in the drift areas of the parts adjacent to the gate; process forming buried diffusion areas in the first and second conductive wells; process forming source/drain having a body contact on a side on the buried diffusion areas in the first and second conductive wells; process forming an insulation film having a contact formed in such way that is exposed the surface of source/drain on the entire surface of the substrate including the gate and isolation membrane; process forming a metal film on the insul

Abstract: This invention describes a manufacturing method for MOSFET devices that are free from reverse short channel effect usually found in such devices made by prior art processes. In contrast to the prior art process sequence, the channel implant is made after the source and drain already formed by implantation and its damage already annealed out. The enhanced diffusion of the channel implant, caused by damage generated point defects and responsible for the reverse short channel effect, is therefore avoided. The channel implantation uses high energy ions to penetrate through the polysilicon gate, forming a threshold voltage adjustment and punch-through barrier layer under the gate. The channel implant through the source/drain regions is deeper than the source/drain junctions so that the junction capacitance is reduced in comparison with the prior art.

Abstract: In order to improve the degree of storage data integration, side walls (32) are selectively formed on side surfaces of word lines (22) to serve as masks for changing ON-state current values of memory cells by changing widths or lengths of active regions (24) of the memory cells, thereby forming a plurality of types of memory cells having different electrical properties. Thus, storage data per memory cell is so multivalued that the number of memory cells is reduced.

Abstract: A two stage threshold adjust implantation process is performed after field oxidation to avoid the effects of dopant redistribution and segregation. At any of several steps in a manufacturing process, only routine implant energy and dose adjustments are required to create a first and a second dopant profile (110, 120) that result in the reduction of edge leakage and threshold voltage sensitivity to device layer thickness of a semiconductor device on a semiconductor on insulator substrate.