Class / Patent application number | Description | Number of patent applications / Date published |
438302000 | Oblique implantation | 30 |
20090233412 | METHOD FOR ANGULAR DOPING OF SOURCE AND DRAIN REGIONS FOR ODD AND EVEN NAND BLOCKS - Stacked gate structures for a NAND string are created on a substrate. Source implantations are performed at a first implantation angle to areas between the stacked gate structures. Drain implantations are performed at a second implantation angle to areas between the stacked gate structures. The drain implantations create lower doped regions of a first conductivity type in the substrate on drain sides of the stacked gate structures. The source implantations create higher doped regions of the first conductivity type in the substrate on source sides of the stacked gate structures. | 09-17-2009 |
20090298249 | DRIVE CURRENT INCREASE IN TRANSISTORS BY ASYMMETRIC AMORPHIZATION IMPLANTATION - By providing a substantially non-damaged semiconductor region between a pre-amorphization region and the gate electrode structure, an increase of series resistance at the drain side during the re-crystallization may be reduced, thereby contributing to overall transistor performance, in particular in the linear operating mode. Thus, symmetric and asymmetric transistor architectures may be achieved with enhanced performance without unduly adding to overall process complexity. | 12-03-2009 |
20090325355 | REDUCING IMPLANT DEGRADATION IN TILTED IMPLANTATIONS BY SHIFTING IMPLANTATION MASKS - In extremely scaled semiconductor devices, an asymmetric transistor configuration may be established on the basis of tilted implantation processes with increased resist height and/or tilt angles during tilted implantation processes by providing an asymmetric mask arrangement for masked transistor elements. For this purpose, the implantation mask may be shifted by an appropriate amount so as to enhance the overall blocking effect for the masked transistors while reducing any shadowing effect of the implantation masks for the non-masked transistors. The shift of the implantation masks may be accomplished by performing the automatic alignment procedure on the basis of “shifted” target values or by providing asymmetrically arranged photolithography masks. | 12-31-2009 |
20100003798 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - A semiconductor device comprises a field-effect transistor arranged in a semiconductor substrate, which transistor has a gate electrode, source/drain impurity diffusion regions, and carbon layers surrounding the source/drain impurity diffusion regions. Each of the carbon layers is provided at an associated of the source/drain impurity diffusion regions and positioned so as to be offset from the front edge of a source/drain extension in direction away from the gate electrode and to surround as profile the associated source/drain impurity diffusion region. | 01-07-2010 |
20100022062 | TRANSITOR HAVING A GERMANIUM IMPLANT REGION LOCATED THEREIN AND A METHOD OF MANUFACTURE THEREFOR - The present invention provides a transistor | 01-28-2010 |
20100068860 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURE THEREOF - There is provided a method by which lightly doped drain (LDD) regions can be formed easily and at good yields in source/drain regions in thin film transistors possessing gate electrodes covered with an oxide covering. A lightly doped drain (LDD) region is formed by introducing an impurity into an island-shaped silicon film in a self-aligning manner, with a gate electrode serving as a mask. First, low-concentration impurity regions are formed in the island-shaped silicon film by using rotation-tilt ion implantation to effect ion doping from an oblique direction relative to the substrate. Low-concentration impurity regions are also formed below the gate electrode at this time. After that, an impurity at a high concentration is introduced normally to the substrate, so forming high-concentration impurity regions. In the above process, a low-concentration impurity region remains below the gate electrode and constitutes a lightly doped drain region. | 03-18-2010 |
20100159663 | METHOD OF FABRICATING HIGH INTEGRATED SEMICONDUCTOR APPARATUS, AND SEMICONDUCTOR APPARATUS FABRICATED THEREBY - The present invention provides a method of fabricating a semiconductor apparatus including a vertical transistor and a semiconductor apparatus fabricated thereby which protect a pillar-shaped channel region to stabilize an operating characteristic of the semiconductor apparatus. The method of fabricating the semiconductor apparatus according to the present invention comprises: forming a pillar-shaped pattern on a semiconductor substrate; depositing a conductive layer surrounding the pattern; changing a feature of some portion of the conductive layer through an ion implanting process to form an oxide film; and removing the oxide film using an etching selectivity difference. | 06-24-2010 |
20100227447 | METHOD OF MANUFACTURING FLASH MEMORY DEVICE - A flash memory device manufacturing process includes the steps of providing a semiconductor substrate; forming two gate structures on the substrate; performing an ion implantation process to form two first source regions in the substrate at two lateral outer sides of the two gate structures; performing a further ion implantation process to form a first drain region in the substrate between the two gate structures; performing a pocket implantation process between the gate structures to form two doped regions in the substrate at two opposite sides of the first drain region; forming two facing L-shaped spacer walls between the two gate structures above the first drain region; performing an ion implantation process to form a second drain region beneath the first drain region, both of which having a steep junction profile compared to the first source regions; and forming a barrier plug above the first drain region. | 09-09-2010 |
20100330763 | METHOD OF CREATING ASYMMETRIC FIELD-EFFECT-TRANSISTORS - The present invention provides a method of forming asymmetric field-effect-transistors. The method includes forming at least a first and a second gate-mask stack on top of a semiconductor substrate, wherein the first and second gate-mask stacks include at least, respectively, a first and a second gate conductor of a first and a second transistor and have, respectively, a top surface, a first side, and a second side with the second side being opposite to the first side; performing a first halo implantation from the first side of the first and second gate-mask stacks at a first angle while applying the first gate-mask stack in preventing the first halo implantation from reaching a first source/drain region of the second transistor, wherein the first angle is equal to or larger than a predetermined value; and performing a second halo implantation from the second side of the first and second gate-mask stacks at a second angle, thereby creating halo implant in a second source/drain region of the second transistor, wherein the first and second angles are measured against a normal to the substrate. | 12-30-2010 |
20110033998 | OPTIMIZED HALO OR POCKET COLD IMPLANTS - An improved method of performing pocket or halo implants is disclosed. The amount of damage and defects created by the halo implant degrades the performance of the semiconductor device, by increasing leakage current, decreasing the noise margin and increasing the minimum gate voltage. The halo or packet implant is performed at cold temperature, which decreases the damage caused to the crystalline structure and improves the amorphization of the crystal. The use of cold temperature also allows the use of lighter elements for the halo implant, such as boron or phosphorus. | 02-10-2011 |
20110070710 | METHOD FOR FABRICATING NOR SEMICONDUCTOR MEMORY STRUCTURE - A method for fabricating a NOR semiconductor memory structure includes: performing a deeply doped source ion implantation process and a lightly doped drain ion implantation process; forming oxide layer walls on two said sides of a gate structure, respectively; performing a pocket implant process with control of an incident angle thereof; and performing a deeply doped drain ion implantation process. Characteristics of the NOR semiconductor memory structure are improved by controllably changing the position of a pocket implant region. | 03-24-2011 |
20110111570 | METHODS OF FABRICATING NON-VOLATILE MEMORY DEVICES INCLUDING DOUBLE DIFFUSED JUNCTION REGIONS - A nonvolatile memory device includes a string selection gate and a ground selection gate on a semiconductor substrate, and a plurality of memory cell gates on the substrate between the string selection gate and the ground selection gate. First impurity regions extend into the substrate to a first depth between ones of the plurality of memory cell gates. Second impurity regions extend into the substrate to a second depth that is greater than the first depth between the string selection gate and a first one of the plurality of memory cell gates immediately adjacent thereto, and between the ground selection gate and a last one of the plurality of memory cell gates immediately adjacent thereto. Related fabrication methods are also discussed. | 05-12-2011 |
20110129978 | METHOD AND STRUCTURE FOR FORMING FINFETS WITH MULTIPLE DOPING REGIONS ON A SAME CHIP - A method for fabrication of features for an integrated circuit includes patterning a first semiconductor structure on a surface of a semiconductor device, and epitaxially growing semiconductor material on opposite sides of the first semiconductor structure to form fins. A first angled ion implantation is applied to one side of the first semiconductor structure to dope a respective fin on the one side. The first semiconductor structure is selectively removed to expose the fins. Fin field effect transistors are formed using the fins. | 06-02-2011 |
20110151636 | Method For Angular Doping Of Source And Drain Regions For Odd And Even NAND Blocks - A method for creating NAND flash memory. Source implantations are performed at a first implantation angle to areas between stacked gate structures of a NAND string. Drain implantations are performed at a second implantation angle to areas between the stacked gate structures. The source implantation can include n-type and p-type materials implanted under different angles, and the drain implantation can include n-type and p-type materials implanted under different angles. Or, the source implantation can include multiple n-type implantations under different angles, and the drain implantation can include multiple n-type implantations under different angles. | 06-23-2011 |
20110171804 | Multilayer Hard Mask - A method for fabricating a semiconductor device is disclosed. In an embodiment, the method may include providing a semiconductor substrate; forming gate material layers over the semiconductor substrate; forming a multi-layer hard mask layer over the gate material layers, wherein the multi-layer hard mask layer includes a plurality of film stacks, each film stack having a silicon oxide layer and a carbon-containing material layer, each film stack having a thickness equal to or less than about 10 angstrom; patterning the multi-layer hard mask layer, forming an opening of the multi-hard mask layer; etching the gate material layers within the opening of the multi-layer hard mask layer, forming a gate structure; performing a tilt-angle ion implantation process to the semiconductor substrate, wherein a first remaining thickness of the multi-layer hard mask layer is less than a first thickness; and thereafter performing an epitaxy growth to the semiconductor substrate, wherein a second remaining thickness of the multi-layer hard mask layer is greater than a second thickness. | 07-14-2011 |
20110230029 | METHOD OF FABRICATING GATE ELECTRODE USING A HARD MASK WITH SPACERS - A method for fabricating a semiconductor device is disclosed. In an embodiment, the method may include providing a semiconductor substrate; forming gate material layers over the semiconductor substrate; forming a hard mask layer over the gate material layers; patterning the hard mask layer to from a hard mask pattern; forming a spacer layer over the hard mask pattern; etching back the spacer layer to form spacers over sidewalls of the hard mask pattern; etching the gate material layers by using the spacers and the hard mask pattern as an etching mask to form a gate structure; and performing a tilt-angle ion implantation process to the semiconductor substrate. | 09-22-2011 |
20120083090 | Method of fabricating an NMOS transistor - A SiC region and a source/drain region are formed such that the SiC region includes a first portion overlapping the source/drain region and a second portion protruding from the source/drain region to a position beneath the LDD region. The concentration of crystalline SiC in the second portion is higher than the concentration of crystalline SiC in the first portion. The SiC region may be formed through a normal implantation before the second spacer is formed, or the SiC region may be formed through a tilt implantation or deposition epitaxially in a recess having a sigma-shape like sidewall after the second spacer is formed. | 04-05-2012 |
20120129311 | METHOD OF MANUFACTURING A TRANSISTOR DEVICE HAVING ASYMMETRIC EMBEDDED STRAIN ELEMENTS - Semiconductor transistor devices and related fabrication methods are provided. An exemplary transistor device includes a layer of semiconductor material having a channel region defined therein and a gate structure overlying the channel region. Recesses are formed in the layer of semiconductor material adjacent to the channel region, such that the recesses extend asymmetrically toward the channel region. The transistor device also includes stress-inducing semiconductor material formed in the recesses. The asymmetric profile of the stress-inducing semiconductor material enhances carrier mobility in a manner that does not exacerbate the short channel effect. | 05-24-2012 |
20120135578 | DOPING OF PLANAR OR THREE-DIMENSIONAL STRUCTURES AT ELEVATED TEMPERATURES - An improved method of doping a workpiece is disclosed. In this method, a film comprising the species to be implanted is introduced to the surface of a planar or three-dimensional workpiece. This film can be grown using CVD, a bath or other means. The workpiece with the film is then subjected to ion bombardment to help drive the dopant into the workpiece. This ion bombardment is performed at elevated temperatures to reduce crystal damage and create a more abrupt doped region. | 05-31-2012 |
20120208338 | SELF ALIGNED IMPACT-IONIZATION MOS (I-MOS) DEVICE AND METHODS OF MANUFACTURE - A method of forming a semiconductor structure, including forming a gate structure on a substrate; performing a first angled implantation on a first side of the gate structure to form a first doped region in the substrate, the first doped region partially extends within a channel of the gate structure and the gate structure blocks the first angled implantation from affecting the substrate on a second side of the gate structure; forming sidewall spacers on sidewalls of the gate; and forming a second doped region in the substrate on the second side of the gate, spaced apart from the channel. | 08-16-2012 |
20130095630 | THRESHOLD MISMATCH AND IDDQ REDUCTION USING SPLIT CARBON CO-IMPLANTATION - An integrated circuit containing MOS transistors may be formed using a split carbon co-implantation. The split carbon co-implant includes an angled carbon implant and a zero-degree carbon implant that is substantially perpendicular to a top surface of the integrated circuit. The split carbon co-implant is done at the LDD and halo implant steps. | 04-18-2013 |
20130295742 | METHOD TO TAILOR LOCATION OF PEAK ELECTRIC FIELD DIRECTLY UNDERNEATH AN EXTENSION SPACER FOR ENHANCED PROGRAMMABILITY OF A PROMPT-SHIFT DEVICE - A method to enhance the programmability of a prompt-shift device is provided, which reduces the programming time to sub-millisecond times, by altering the extension and halo implants, instead of simply omitting the same from one side of the device as is the case in the prior art prompt-shift devices. In one embodiment, no additional masks are employed. The altered extension implant is performed at a reduced ion dose as compared to a conventional extension implant process, while the altered halo implant is performed at a higher ion dose than a conventional halo implant. The altered halo/extension implant shifts the peak of the electrical field to under an extension dielectric spacer. | 11-07-2013 |
20140017870 | Method for Inhibiting Programming Disturbance of Flash Memory - Disclosed herein is a method for inhibiting a programming disturbance of a flash memory, which relates to a technical field of a non-volatile memory in ultra-large-scale integrated circuit fabrication technologies. In the present invention, an dopant gradient of a PN junction between a substrate and a drain is reduced by adding a step of performing an angled ion implantation of donor dopants into a standard process for a flash memory, so that an electric field of the PN junction between the substrate and the drain is reduced, and consequently the programming disturbance is inhibited. Meanwhile, a dopant gradient of the PN junction between a channel and the drain is maintained, so that an electric field of the PN junction between the channel and the drain, which is necessary for programming, is maintained, and thus the programming efficiency and the programming speed can be ensured. The programming disturbance can be effectively inhibited without increasing numbers of masks used for photolithography according to the invention, thus the present invention is significantly advantageous to the improvement of the flash memory reliability. | 01-16-2014 |
20140087538 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device is disclosed. In one embodiment, the method comprises: forming a gate stack on a substrate, wherein the gate stack comprises a gate dielectric layer and a gate conductor layer; selectively etching end portions of the gate dielectric layer to form gaps; and filling a material for the gate dielectric layer into the gaps. | 03-27-2014 |
20140113425 | METHOD OF FABRICATING SEMICONDUCTOR DEVICE - A method of fabricating a semiconductor device includes the following steps. At first, at least a gate structure is formed on a substrate. Subsequently, a first material layer and a second material layer sequentially formed on the substrate conformally cover the gate structure. Subsequently, an implantation process is performed on the second material layer, and a wet etching process is further performed to remove a part of the second material layer to form a remaining second material layer. Furthermore, a dry etching process is performed to remove a part of the remaining second material layer to form a partial spacer. | 04-24-2014 |
20140206170 | METHOD OF FABRICATING MOS DEVICE - Provided is a method of fabricating a MOS device including the following steps. At least one gate structure is formed on a substrate, wherein the gate structure includes a gate conductive layer and a hard mask layer disposed on the gate conductive layer. A first implant process is performed to form source and drain extension regions in the substrate, wherein the gate conductive layer is covered by the hard mask layer. A process is of removing the hard mask layer is performed to expose the surface of the gate conductive layer. A second implant process is performed to form pocket doped regions in the substrate, wherein the gate conductive layer is not covered by the hard mask layer. | 07-24-2014 |
20140357042 | SPACER STRESS RELAXATION - A known problem when manufacturing transistors is the stress undesirably introduced by the spacers into the transistor channel region. In order to solve this problem, the present invention proposes an ion implantation aimed at relaxing the stress of the spacer materials. The relax implantation is performed after the spacer has been completely formed. The relax implantation may be performed after a silicidation process or after an implantation step in the source and drain regions followed by an activation annealing and before performing the silicidation process. | 12-04-2014 |
20150044847 | METHOD OF MANUFACTURING AN INTEGRATED CIRCUIT - A method of forming an integrated circuit comprises forming a first doped region in a substrate using a first angle ion implantation performed on a first side of a gate structure. The gate structure has a length in a first direction and a width in a second direction. The method also comprises forming a second doped region in the substrate using a second angle ion implantation performed on a second side of the gate structure. The first angle ion implantation has a first implantation angle with respect to the second direction and the second angle ion implantation has a second implantation angle with respect to the second direction. Each of the first implantation angle and the second implantation angle is substantially larger than 0° and less than 90°. | 02-12-2015 |
20150056776 | METHOD OF MANUFACTURING MOS-TYPE SEMICONDUCTOR DEVICE - A method of manufacturing a MOS-type semiconductor device capable of increasing the thickness of a gate oxide film and obtaining high gate withstanding power and reduced switching loss without increasing a gate threshold voltage Vth is provided. A p-type well region is selectively formed on one principle surface of a semiconductor substrate having an n-type low impurity concentration layer by using an oxide film as a mask. Subsequently, a resist mask is formed on the surface of the p-type well region so as to be separated from the oxide film mask, and an n | 02-26-2015 |
20160049497 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE - A method for fabricating semiconductor device is disclosed. The method includes the steps of: providing a substrate; forming a gate structure on the substrate; forming a lightly doped drain in the substrate; and performing a first implantation process for implanting fluorine ions at a tiled angle into the substrate and part of the gate structure. | 02-18-2016 |