Class / Patent application number | Description | Number of patent applications / Date published |
438217000 | Doping of semiconductor channel region beneath gate insulator (e.g., threshold voltage adjustment, etc.) | 28 |
20080305590 | HIGH PERFORMANCE CMOS DEVICES AND METHODS FOR MAKING SAME - An integrated circuit having high performance CMOS devices with good short channel effects may be made by forming a gate structure over a substrate; forming pocket implant regions and source/drain extensions in the substrate; forming spacers along sides of the gate structure; and thermal annealing the substrate when forming the spacers, the thermal annealing performed at an ultra-low temperature. An integrated circuit having high performance CMOS devices with low parasitic junction capacitance may be made by forming a gate structure over a substrate; forming pocket implant regions and source/drain extensions in the substrate; forming spacers along sides of the gate structure; performing a low dosage source/drain implant; and performing a high dosage source/drain implant. | 12-11-2008 |
20090023257 | METHOD OF CONTROLLING METAL SILICIDE FORMATION - Methods of processing silicon substrates to form metal silicide layers thereover having more uniform thicknesses are provided herein. In some embodiments, a method of processing a substrate includes providing a substrate having a plurality of exposed regions comprising silicon, wherein at least two of the plurality of exposed regions have a different rate of formation of a metal silicide layer thereover; doping at least one of the exposed regions to control the rate of formation of a metal silicide layer thereover; and forming a metal silicide layer upon the exposed regions of the substrate, wherein the metal silicide layer has a reduced maximum thickness differential between the exposed regions. | 01-22-2009 |
20090170256 | ANNEALING METHOD FOR SIGE PROCESS - A method of forming a transistor comprising forming a gate structure over an n-type semiconductor body and forming recesses substantially aligned to the gate structure in the semiconductor body. Silicon germanium is then epitaxially grown in the recesses and a silicon cap layer is formed over the silicon germanium. Further introduction of impurities into the silicon germanium to increase the melting point thereof and implanting p-type source/drain regions in the semiconductor body is included in the method. The method concludes with performing a high temperature thermal treatment. | 07-02-2009 |
20090170257 | METHOD OF MANUFACTURING MOS TRANSISTOR - A method of manufacturing a transistor may include: forming a first well over a silicon substrate; forming a first mask pattern over the silicon substrate and using the formed first mask pattern to form a second well; removing the first mask pattern; forming a second mask pattern over the silicon substrate and using the formed second mask pattern to form a first drift region; removing the second mask pattern; forming a third mask pattern and using the formed third mask pattern to form a second drift region; removing the third mask pattern; forming a field oxide film over the silicon substrate; and introducing first conductive impurity ions into an upper surface of the silicon substrate by channel ion implantation. | 07-02-2009 |
20090286366 | FORMATION OF STANDARD VOLTAGE THRESHOLD AND LOW VOLTAGE THRESHOLD MOSFET DEVICES - Wells are formed in a substrate where standard Vt and low Vt devices of both a first and second type are to be fabricated. Wells defining the locations of first type standard Vt devices are masked, and a first voltage threshold implant adjustment is performed within wells defining the second type standard Vt devices, and each of the first and second type low Vt devices. Wells that define the locations of second type standard Vt devices are masked, and a second voltage threshold implant adjustment is performed to the wells defining the first type standard Vt devices, and each of the first and second type low Vt devices. Doped polysilicon gate stacks are then formed over the wells. Performance characteristics and control of each device Vt is controlled by regulating at least one of the first and second voltage threshold implant adjustments, and the polysilicon gate stack doping. | 11-19-2009 |
20100203691 | High Voltage CMOS Devices - A transistor suitable for high-voltage applications is provided. The transistor is formed on a substrate having a deep well of a first conductivity type. A first well of the first conductivity type and a second well of a second conductivity type are formed such that they are not immediately adjacent each other. The well of the first conductivity type and the second conductivity type may be formed simultaneously as respective wells for low-voltage devices. In this manner, the high-voltage devices may be formed on the same wafer as low-voltage devices with fewer process steps, thereby reducing costs and process time. A doped isolation well may be formed adjacent the first well on an opposing side from the second well to provide further device isolation. | 08-12-2010 |
20110081754 | METHODS FOR OBTAINING GATE STACKS WITH TUNABLE THRESHOLD VOLTAGE AND SCALING - Methods of forming complementary metal oxide semiconductor (CMOS) structures with tunable threshold voltages are provided. The methods disclose a technique of obtaining selective placement of threshold voltage adjusting materials on a semiconductor substrate by using a block mask prior to deposition of the threshold voltage adjusting materials. The block mask is subsequently removed to obtain a patterned threshold voltage adjusting material on the semiconductor substrate. The methods are material independent and can be used in sequence for both nFET threshold voltage adjusting materials and pFET threshold voltage adjusting materials. | 04-07-2011 |
20110111566 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD OF THE SAME - Manufacturing technique for a semiconductor device having a first MISFET of an n channel-type and a second MISFET of a p channel type, including forming a first insulating film composed of a silicon oxide film or a silicon oxynitride film on a semiconductor substrate for forming a gate insulating film of the respective MISFETs; depositing metal elements on the first insulating film; forming of a silicon film on the first insulating film for the forming of a gate electrode of the respective MISFETs; and producing the respective gate electrodes by patterning the silicon film. The depositing of the metal films on the first insulating film is such that there is produced in the vicinity of the interface between the gate electrode and the gate insulating film a surface density of the metal elements within a range of 1×10 | 05-12-2011 |
20120045874 | CMOS INTEGRATION METHOD FOR OPTIMAL IO TRANSISTOR VT - Various embodiments provide methods for fabricating dual supply voltage CMOS devices with a desired I/O transistor threshold voltage. The dual supply voltage CMOS devices can be fabricated in a semiconductor substrate that includes isolated regions for a logic NMOS transistor, a logic PMOS transistor, an I/O NMOS transistor, and an I/O PMOS transistor. Specifically, the fabrication can first set and/or adjust the threshold voltage (V | 02-23-2012 |
20120045875 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE - A method of manufacturing a semiconductor device includes: forming first to third gate electrodes in first to third regions, respectively; forming a first mask pattern covering the second region while exposing the first and third regions; forming p-type source drain extensions and p-type pocket regions by ion implantation using the first mask pattern as a mask; forming n-type source drain extensions by ion implantation using the first mask pattern as a mask; forming a second mask pattern covering the first and third regions while exposing the second region; and forming p-type pocket regions by implanting ions of indium into the silicon substrate with the second mask pattern being used as a mask. | 02-23-2012 |
20120156838 | MULTI-GATE NON-PLANAR FIELD EFFECT TRANSISTOR STRUCTURE AND METHOD OF FORMING THE STRUCTURE USING A DOPANT IMPLANT PROCESS TO TUNE DEVICE DRIVE CURRENT - Disclosed are embodiments of a semiconductor structure that includes one or more multi-gate field effect transistors (MUGFETs), each MUGFET having one or more semiconductor fins. In the embodiments, dopant implant region is incorporated into the upper portion of the channel region of a semiconductor fin in order to selectively modify (i.e., decrease or increase) the threshold voltage within that upper portion relative to the threshold voltage in the lower portion and, thereby to selectively modify (i.e., decrease or increase) device drive current. In the case of a multiple semiconductor fins, the use of implant regions, the dopant conductivity type in the implant regions and/or the sizes of the implant regions can be varied from fin to fin within a multi-fin MUGFET or between different single and/or multi-fin MUGFETs so that individual device drive current can be optimized. Also disclosed herein are embodiments of a method of forming the semiconductor structure. | 06-21-2012 |
20120190159 | ASYMMETRIC SILICON-ON-INSULATOR SRAM CELL - A memory cell having N transistors including at least one pair of access transistors, one pair of pull-down transistors, and one pair of pull-up transistors to form a memory cell, wherein N is an integer at least equal to six, wherein each of the access transistors and each of the pull-down transistors is a same one of an n-type or a p-type transistor, and each of the pull-up transistors is the other of an n-type or a p-type transistor, wherein at least one of the pair of the pull down transistors and the pair of the pull up transistors are asymmetric. | 07-26-2012 |
20120264263 | Structure and Fabrication of Like-polarity Field-effect Transistors Having Different Configurations of Source/Drain Extensions, Halo Pockets, and Gate Dielectric Thicknesses - A group of high-performance like-polarity insulated-gate field-effect transistors ( | 10-18-2012 |
20120302019 | NON-RELAXED EMBEDDED STRESSORS WITH SOLID SOURCE EXTENSION REGIONS IN CMOS DEVICES - A method of forming a field effect transistor (FET) device includes forming a patterned gate structure over a substrate; forming a solid source dopant material on the substrate, adjacent sidewall spacers of the gate structure; performing an anneal process at a temperature sufficient to cause dopants from the solid source dopant material to diffuse within the substrate beneath the gate structure and form source/drain extension regions; following formation of the source/drain extension regions, forming trenches in the substrate adjacent the sidewall spacers, corresponding to source/drain regions; and forming an embedded semiconductor material in the trenches so as to provide a stress on a channel region of the substrate defined beneath the gate structure. | 11-29-2012 |
20120309145 | METHODS OF MANUFACTURING SEMICONDUCTOR DEVICES - Methods of manufacturing semiconductor devices include providing a substrate including a NMOS region and a PMOS region, implanting fluorine ions into an upper surface of the substrate, forming a first gate electrode of the NMOS region and a second gate electrode of the PMOS region on the substrate, forming a source region and a drain region in portions of the substrate, which are adjacent to two lateral surfaces of the first gate electrode and the second gate electrode, respectively, and performing a high-pressure heat-treatment process on an upper surface of the substrate by using non-oxidizing gas. | 12-06-2012 |
20130109141 | TRANSISTORS WITH DIFFERENT THRESHOLD VOLTAGES | 05-02-2013 |
20130196476 | HIGH THRESHOLD VOLTAGE NMOS TRANSISTORS FOR LOW POWER IC TECHNOLOGY - Transistors exhibiting different electrical characteristics such as different switching threshold voltage or different leakage characteristics are formed on the same chip or wafer by selectively removing a film or layer which can serve as an out-diffusion sink for an impurity region such as a halo implant and out-diffusing an impurity such as boron into the out-diffusion sink, leaving the impurity region substantially intact where the out-diffusion sink has been removed. In forming CMOS integrated circuits, such a process allows substantially optimal design for both low-leakage and low threshold transistors and allows a mask and additional associated processes to be eliminated, particularly where a tensile film is employed to increase electron mobility since the tensile film can be removed from selected NMOS transistors concurrently with removal of the tensile film from PMOS transistors. | 08-01-2013 |
20130280871 | SEMICONDUCTOR DEVICE AND METHOD OF FABRICATING THE SAME - A method of fabricating a semiconductor device includes performing pre-halo ion implantation on a semiconductor substrate, forming a first epitaxial layer over the entire upper surface of the semiconductor substrate, forming a second epitaxial layer over the entire surface of the first epitaxial layer, and forming a transistor at an active region of the second epitaxial layer. The first epitaxial layer prevents the ions implanted in the semiconductor substrate in the pre-halo implantation process from diffused into the second epitaxial layer under the effects of a process used to form the transistor. | 10-24-2013 |
20130323892 | METHODS OF PERFORMING HIGHLY TILTED HALO IMPLANTATION PROCESSES ON SEMICONDUCTOR DEVICES - One illustrative method disclosed herein involves forming first and second gate structures that include a cap layer for a first transistor device and a second transistor device, respectively, wherein the first and second transistors are oriented transverse to one another, performing a first halo ion implant process to form first halo implant regions for the first transistor with the cap layer in position in the first gate structure of the first transistor, removing the cap layer from at least the second gate structure of the second transistor and, after removing the cap layer, performing a second halo ion implant process to form second halo implant regions for the second transistor, wherein the first and second halo implant processes are performed at transverse angles relative to the substrate. | 12-05-2013 |
20130330890 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE WITH OFFSET SIDEWALL STRUCTURE - A method of manufacturing a semiconductor device with NMOS and PMOS transistors is provided. The semiconductor device can lessen a short channel effect, can reduce gate-drain current leakage, and can reduce parasitic capacitance due to gate overlaps, thereby inhibiting a reduction in the operating speed of circuits. An N-type impurity such as arsenic is ion implanted to a relatively low concentration in the surface of a silicon substrate ( | 12-12-2013 |
20140273367 | INTEGRATED CIRCUITS AND METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH GATE ELECTRODE STRUCTURE PROTECTION - Integrated circuits and methods for fabricating integrated circuits are provided herein. In an embodiment of a method for fabricating integrated circuits, a P-type gate electrode structure and an N-type gate electrode structure are formed overlying a semiconductor substrate. The gate electrode structures each include a gate electrode that overlies a gate dielectric layer and a nitride cap that overlies the gate electrode. Conductivity determining ions are implanted into the semiconductor substrate using the P-type gate electrode structure and the N-type gate electrode structure as masks to form a source region and a drain region for the P-type gate electrode structure and the N-type gate electrode structure. The nitride cap remains overlying the N-type gate electrode structure during implantation of the conductivity determining ions into the semiconductor substrate to form the source region and the drain region for the N-type gate electrode structure. | 09-18-2014 |
20140357028 | METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH THE IMPLANTATION OF FLUORINE - A method for fabricating an integrated circuit includes forming a first gate electrode structure above a first active region and a second gate electrode structure above a second active region, forming a sacrificial spacer on sidewalls of the first and second gate electrode structures, and forming deep drain and source regions selectively in the first and second active regions by using the sacrificial spacer as an implantation mask. The method further includes forming drain and source extension and halo regions in the first and second active regions after removal of the sacrificial spacer and forming a fluorine implant region in the halo region of the first active region before or after formation of the drain and source extension and halo regions. | 12-04-2014 |
20140370672 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE - In a method for fabricating a semiconductor device, a first gate electrode and a second gate electrode are provided on a substrate, the first gate electrode and the second gate electrode being formed in a first region and a second region of the substrate, respectively. A conductive buffer layer is formed along sidewalls of the first gate electrode and the second gate electrode and on upper surfaces of the first gate electrode and second gate electrode. A first mask pattern covering the first region of the substrate on the buffer layer is formed. A first impurity region is formed in the substrate at sides of the second gate electrode using the first mask pattern as a mask of an ion implantation process. | 12-18-2014 |
20150325486 | SEMICONDUCTOR DEVICE AND METHOD FOR PRODUCING THE SAME - Provided are a semiconductor device having a high breakdown voltage and attaining the restraint of the action of a parasite bipolar transistor, and a method for producing the device. A high-breakdown-voltage p-channel-type transistor included in the semiconductor device has a first n-type semiconductor layer arranged in a semiconductor substrate and at a main-surface-side (upside) of a p-type region in the semiconductor substrate, and a local n-type buried region arranged just below a first p-type dopant region to contact the first n-type semiconductor layer. | 11-12-2015 |
20160071775 | CMOS FABRICATION - A method of manufacturing a memory device includes an nMOS region and a pMOS region in a substrate. A first gate is defined within the nMOS region, and a second gate is defined in the pMOS region. Disposable spacers are simultaneously defined about the first and second gates. The nMOS and pMOS regions are selectively masked, one at a time, and LDD and Halo implants performed using the same masks as the source/drain implants for each region, by etching back spacers between source/drain implant and LDD/Halo implants. All transistor doping steps, including enhancement, gate and well doping, can be performed using a single mask for each of the nMOS and pMOS regions. Channel length can also be tailored by trimming spacers in one of the regions prior to source/drain doping. | 03-10-2016 |
20160172466 | METHOD TO REDUCE ETCH VARIATION USING ION IMPLANTATION | 06-16-2016 |
20160204038 | METHODS FOR FABRICATING INTEGRATED CIRCUITS WITH IMPROVED IMPLANTATION PROCESSES | 07-14-2016 |
20180025948 | METHOD OF MANUFACTURING A CMOS TRANSISTOR | 01-25-2018 |