Class / Patent application number | Description | Number of patent applications / Date published |
438527000 | Including multiple implantation steps | 71 |
20080200016 | Method of fabricating nonvolatile semiconductor memory device - A method of fabricating a nonvolatile semiconductor memory device includes the steps of: (a) forming a layered dielectric film on the semiconductor substrate; (b) forming a first conductive film on the layered dielectric film; (c) forming a first dielectric film on the first conductive film; (d) patterning the first dielectric film and the first conductive film to form a layered pattern composed of first dielectric films and first conductive films; and (e) implanting a first impurity along a direction having an inclination angle to a normal direction to a principal plane of the semiconductor substrate by using the layered pattern as a mask to form a first impurity diffusion layer being the same in conductivity type as the semiconductor substrate, wherein, step (d) includes patterning the first dielectric film to form the first dielectric films having a shape with a width narrower in an upper surface than in a lower surface. | 08-21-2008 |
20080268624 | Method of Fabricating Semiconductor Device - This invention relates to a method of fabricating a semiconductor device. A P well for a cell junction may be formed by performing an ion implantation process employing a zero tilt condition. Stress caused by collision between a dopant and a Si lattice within a semiconductor substrate may be minimized and, therefore stress remaining within the semiconductor substrate may be minimized. Accordingly, Number Of Program (NOP) fail by disturbance caused by stress remaining within a channel junction may be reduced. Further, a broad doping profile may be formed at the interface of trenches by using BF | 10-30-2008 |
20080268625 | ENHANCING TRANSISTOR CHARACTERISTICS BY A LATE DEEP IMPLANTATION IN COMBINATION WITH A DIFFUSION-FREE ANNEAL PROCESS - By combining an anneal process for adjusting the effective channel length and a substantially diffusion-free anneal process performed after a deep drain and source implantation, the vertical extension of the drain and source region may be increased substantially without affecting the previously adjusted channel length. In this manner, in SOI devices, the drain and source regions may extend down to the buried insulating layer, thereby reducing the parasitic capacitance, while the degree of dopant activation and thus series resistance in the extension regions may be improved. Furthermore, less critical process parameters during the anneal process for adjusting the channel length may provide the potential for reducing the lateral dimensions of the transistor devices. | 10-30-2008 |
20080268626 | Semiconductor device having a plurality of kinds of wells and manufacturing method thereof - A semiconductor device has a configuration in which more than three kinds of wells are formed with small level differences. One kind of well from among the more than three kinds of wells has a surface level higher than other kinds of wells from among the more than three kinds of wells. The one kind of well is formed adjacent to and self-aligned to at least one kind of well from among the other kinds of wells. The other kinds of wells are different in one of a conductivity type, an impurity concentration and a junction depth, and include at least two kinds of wells having the same surface level. | 10-30-2008 |
20080318401 | Power semiconductor device for suppressing substrate recirculation current and method of fabricating power semiconductor device - A power semiconductor device has a first region in which a transistor is formed, a third region in which a control element is formed, and a second region for separating the first region and the third region. The power semiconductor device includes a substrate of a first conductive type and a semiconductor region of a second conductive type arranged on the substrate, and a highly-doped buried layer of the second conductive type and a highly-doped bottom layer of the first conductive type are arranged between the substrate and the semiconductor region, and the first highly-doped bottom layer of the first conductive type is arranged on a top side and a bottom side of the highly-doped buried layer in the first region and extends by a predetermined distance to the second region, and a first isolation region is arranged on the highly-doped bottom layer extending from the first region in the second region, and a highly-doped region of the second conductive type is arranged on the highly-doped buried layer, and a second isolation region is arranged on a second highly-doped bottom layer of the first conductive type . By such structure, parasitic bipolar junction transistors in the first isolation region and the second isolation region can be electrically separated from the third region. | 12-25-2008 |
20090029536 | Bipolar transistors with vertical structures - A method for fabricating a bipolar transistor includes forming a vertical sequence of semiconductor layers, forming an implant mask on the last formed semiconductor layer, and implanting dopant ions into a portion of one or more of the semiconductor layers. The sequence of semiconductor layers includes a collector layer, a base layer that is in contact with the collector layer, and an emitter layer that is in contact with the base layer. The implanting uses a process in which the implant mask stops dopant ions from penetrating into a portion of the sequence of layers. | 01-29-2009 |
20090042377 | METHOD FOR FORMING SELF-ALIGNED WELLS TO SUPPORT TIGHT SPACING - Methods include utilizing a single mask layer to form tightly spaced, adjacent first-type and second-type well regions. The mask layer is formed over a substrate in a region in which the second-type well regions will be formed. The first-type well regions are formed in the exposed portions of the substrate. Then, the second-type well-regions are formed through the resist mask. | 02-12-2009 |
20090081858 | Sputtering-Less Ultra-Low Energy Ion Implantation - Methods of implanting dopants into a silicon substrate using a predeposited sacrificial material layer with a defined thickness that is removed by sputtering effect is provided. | 03-26-2009 |
20090170297 | Method of Fabricating Semiconductor Device Having Gate Spacer Layer With Uniform Thickness - A method of fabricating a semiconductor device having a gate spacer layer with a uniform thickness wherein a gate electrode layer pattern is formed on a substrate and ion implantation processes of respectively different doses are formed on side walls of the gate electrode layer patterns in respective first and second regions of the substrate. A first gate spacer layer is formed on the gate electrode layer pattern where the ion implantation process is performed. A second gate spacer layer is formed on the first gate spacer layer. | 07-02-2009 |
20090186471 | METHOD OF FABRICATING SEMICONDUCTOR DEVICE FOR REDUCING THERMAL BURDEN ON IMPURITY REGIONS OF PERIPHERAL CIRCUIT REGION - A method of fabricating a semiconductor device for reducing a thermal burden on impurity regions of a peripheral circuit region includes preparing a substrate including a cell active region in a cell array region and peripheral active regions in a peripheral circuit region. A cell gate pattern and peripheral gate patterns may be formed on the cell active region and the peripheral active regions. First cell impurity regions may be formed in the cell active region. A first insulating layer and a sacrificial insulating layer may be formed to surround the cell gate pattern and the peripheral gate patterns. Cell conductive pads may be formed in the first insulating layer to electrically connect the first cell impurity regions. The sacrificial insulating layer may be removed adjacent to the peripheral gate patterns. First and second peripheral impurity regions may be sequentially formed in the peripheral active regions adjacent to the peripheral gate patterns. | 07-23-2009 |
20090203200 | GATE PATTERNING SCHEME WITH SELF ALIGNED INDEPENDENT GATE ETCH - A method for self-aligned gate patterning is disclosed. Two masks are used to process adjacent semiconductor components, such as an nFET and pFET that are separated by a shallow trench isolation region. The mask materials are chosen to facilitate selective etching. The second mask is applied while the first mask is still present, thereby causing the second mask to self align to the first mask. This avoids the undesirable formation of a stringer over the shallow trench isolation region, thereby improving the yield of a semiconductor manufacturing operation. | 08-13-2009 |
20090253253 | METHOD OF ADJUSTING FDSOI THRESHOLD VOLTAGE THROUGH OXIDE CHARGES GENERATION IN THE BURIED OXIDE - Different performance MOSFET Fully Depleted devices can be achieved on a single chip by varying the Vt through ion implantation. The integration of multiple Vt can be achieved through the selection of a metal gate stack with suitable effective WF for one semiconductor device to be included on a chip. Then, an ion implantation, with a dopant such as F, can be selectively performed to achieve proper Vt for other semiconductor devices on the chip. | 10-08-2009 |
20090305490 | METHOD FOR PRODUCING SEMICONDUCTOR DEVICE - A method for producing a semiconductor device includes forming an electrically conductive pattern so as to overlap in a plan view with part of a semiconductor layer provided on a substrate, on the opposite side of the substrate side of the semiconductor layer; implanting an impurity into the semiconductor layer using the electrically conductive pattern as a mask; reducing a superimposed region that is a region where the electrically conductive pattern and the semiconductor layer overlap with each other in a plan view by removing part of the electrically conductive pattern after the implantation of the impurity; and implanting the impurity into the semiconductor layer using the electrically conductive pattern as a mask after the reduction of the superimposed region. | 12-10-2009 |
20100009527 | INTEGRATED CIRCUIT SYSTEM EMPLOYING SINGLE MASK LAYER TECHNIQUE FOR WELL FORMATION - A method for manufacturing an integrated circuit system that includes: providing a substrate; forming a mask layer over the substrate; implanting a first well through an opening in the mask layer into the substrate; and implanting a second well through the mask layer and the opening via a single implant into the substrate. | 01-14-2010 |
20100062589 | IMPLANTING A SOLAR CELL SUBSTRATE USING A MASK - Various masks for use with ion implantation equipment are disclosed. In one embodiment, the masks are formed by assembling a collection of segments and spacers to create a mask having the desired configuration. This collection of parts is held together with a carrier of frame. In another embodiment, a panel is formed by machining open-ended slots into a substrate, so as to form a comb-shaped device. Two such panels may be connected together to form a mask. In other embodiments, the panels may be used sequentially in an ion implantation process to create interdigitated back contacts. In another embodiment, multiple masks are overlaid so as to create implant patterns that cannot be created effectively using a single mask. | 03-11-2010 |
20100093162 | Method of manufacturing semiconductor device - A method of manufacturing a semiconductor device wherein semiconductor elements (e.g., transistors) respectively formed in multiple independent wells have the same characteristics with the number of production process steps being reduced. A P-type well as an area of a first conductivity type is formed on a semiconductor substrate. Then, second and fourth wells as two regions of a second conductivity type are formed apart from each other in the P-type well, and a first buried well of N-type as a first buried region of the second conductivity type to connect the second and fourth wells is formed at the bottom of a third well (part of the area of the first conductivity type) sandwiched between the second and fourth wells. In this way, a triple well is formed on the semiconductor substrate. | 04-15-2010 |
20100093163 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - The present invention provides a method for manufacturing a semiconductor device which includes a step of forming one optional impurity region in a semiconductor substrate at a place apart from the surface thereof, and in the method described above, ion implantation is performed a plurality of times while the position of an end portion of a mask pattern used for ion implantation is changed. | 04-15-2010 |
20100099244 | PARTIAL IMPLANTATION METHOD FOR SEMICONDUCTOR MANUFACTURING - Disclosed herein is a partial implantation method for manufacturing semiconductor devices. The method involves implantation of dopant ions at different densities into a plurality of wafer regions, including first and second regions, defined in a wafer by means of a boundary line. In the method, first, second and third implantation zones are defined. The first implantation zone is the remaining part of the first region except for a specific part of the first region close to the boundary line, the second implantation zone is the remaining part of the second region except for a specific part of the second region close to the boundary line, and the third implantation zone is the remaining part of the wafer except for the first and second implantation zones. Then, dopant ions are implanted into the first implantation zone at a first density, into the second implantation zone at a second density different from the first density, and into the third implantation zone at a third density that is a midway value between the first and second densities. | 04-22-2010 |
20100159681 | Ion implantation method and method for manufacturing semiconductor apparatus - An ion implantation method according to the present invention is provided, to selectively implant ions in a semiconductor area, which is a semiconductor substrate or a semiconductor layer formed on the semiconductor substrate, using an ion implantation mask, the method including the steps of: forming the ion implantation mask by exposing and developing of a photosensitive material film, in such a manner that the ion implantation mask includes a mask opening and a mask thin film section; and implanting ions using the ion implantation mask as a mask to form a plurality of diffusion layers with different diffusion depths in the semiconductor area corresponding to the mask opening section and the mask thin film section. | 06-24-2010 |
20100159682 | Method of removing photoresist - A method includes forming a photoresist pattern over a certain portion of a material layer to expose an ion implantation region, implanting impurities in the ion implantation region of the material layer using the photoresist pattern as an ion implantation barrier, and removing the photoresist pattern using plasma of a gas mixture including a hydrocarbon-based gas. | 06-24-2010 |
20100197126 | USE OF CHAINED IMPLANTS IN SOLAR CELL - The manufacture of solar cells is simplified and cost reduced through by performing successive ion implants, without an intervening thermal cycle. In addition to reducing process time, the use of chained ion implantations may also improve the performance of the solar cell. In another embodiment, two different species are successively implanted without breaking vacuum. In another embodiment, the substrate is implanted, then flipped such that it can be and implanted on both sides before being annealed. In yet another embodiment, one or more different masks are applied and successive implantations are performed without breaking the vacuum condition, thereby reducing the process time. | 08-05-2010 |
20100233871 | METHOD FOR GENERATING TWO DIMENSIONS FOR DIFFERENT IMPLANT ENERGIES - A method for fabricating an integrated circuit device is disclosed. The method includes providing a substrate; forming a first hard mask layer over the substrate; patterning the first hard mask layer to form one or more first openings having a first critical dimension; performing a first implantation process on the substrate; forming a second hard mask layer over the first hard mask layer to form one or more second openings having a second critical dimension; and performing a second implantation process. | 09-16-2010 |
20100240201 | IMPLANTATION OF MULTIPLE SPECIES TO ADDRESS COPPER RELIABILITY - A first species and a second species are implanted into a conductor of a substrate, which may be copper. The first species and second species may be implanted sequentially or at least partly simultaneously. Diffusion of the first species within the conductor of the substrate is prevented by the presence of the second species. In one particular example, the first species is silicon and the second species is nitrogen, although other combinations are possible. | 09-23-2010 |
20100273322 | METHOD OF PROCESSING A SUBSTRATE HAVING A NON-PLANAR SURFACE - A technique for conformal processing of a substrate having a non-planar surface is disclosed. The technique includes several stages. In a first stage, some surfaces of the substrate are effectively processed. During a second stage, these surfaces are treated to limit or eliminate further processing of these surfaces. During a third stage, other surfaces of the substrate are processed. In some applications, the surfaces that are perpendicular, or substantially perpendicular to the flow of particles are processed in the first and second stages, while other surfaces are processed in the third stage. In some embodiments, the second stage includes the deposition of a film on the substrate. | 10-28-2010 |
20100297837 | Implantation using a hardmask - A method for processing CMOS wells, and performing multiple ion implantations with the use of a single hard mask is disclosed. The method includes forming and patterning a hardmask over a substrate, whereby the hardmask attains a first opening. The substrate may be a semiconductor substrate. The method further includes performing a first ion implantation, during which, outside the first opening the hardmask is essentially preventing ions from reaching the substrate. The method further involves the application of a photoresist in such a manner that the photoresist is covering the hardmask, and it is also filling up the first opening. This is followed by using the photoresist to pattern the hardmask, whereby the hardmask attains a second opening. The method further includes performing a second ion implantation, during which, outside the second opening, the hardmask and the photoresist, which fills the first opening, are essentially preventing ions from reaching the substrate. The two ion implantations may be used to form the two type of CMOS wells. | 11-25-2010 |
20110207310 | SEMICONDUCTOR DEVICE WITH A FIELD STOP ZONE AND PROCESS OF PRODUCING THE SAME - Embodiments discussed herein relate to processes of producing a field stop zone within a semiconductor substrate by implanting dopant atoms into the substrate to form a field stop zone between a channel region and a surface of the substrate, at least some of the dopant atoms having energy levels of at least 0.15 eV below the energy level of the conduction band edge of semiconductor substrate; and laser annealing the field stop zone. | 08-25-2011 |
20110230039 | DOPANT PROFILE TUNING FOR MOS DEVICES BY ADAPTING A SPACER WIDTH PRIOR TO IMPLANTATION - By selectively modifying the spacer width, for instance, by reducing the spacer width on the basis of implantation masks, an individual adaptation of dopant profiles may be achieved without unduly contributing to the overall process complexity. For example, in sophisticated integrated circuits, the performance of transistors of the same or different conductivity type may be individually adjusted by providing different sidewall spacer widths on the basis of an appropriate masking regime. | 09-22-2011 |
20110250741 | Method of producing semiconductor device, solid-state imaging device, method of producing electric apparatus, and electric apparatus - There is provided a method of producing a semiconductor device. The method includes the steps of: forming a first hard mask having an opening above a substrate; forming a sacrificial film above a side surface of the opening of the first hard mask; forming a second hard mask in the opening having the sacrificial film above the side surface; removing the sacrificial film after the second hard mask is formed; ion implanting a first conductivity-type impurity through the first hard mask; and ion implanting a second conductivity-type impurity through the first and second hard masks. | 10-13-2011 |
20110287617 | METHOD OF MANUFACTURING SUPER-JUNCTION SEMICONDUCTOR DEVICE - A method of manufacturing a super-junction semiconductor device facilitates suppressing the shape change caused in the alignment mark in the upper epitaxial layer transferred from the alignment mark in the lower epitaxial layer to be small enough to detect the transferred alignment mark with a few additional steps, even if the epitaxial layer growth rate is high. Alignment mark groups, each formed of trenches including parallel linear planar patterns and used in any of the multiple epitaxial layer growth cycles, are formed collectively on a scribe line between semiconductor chip sections; and the mesa region width between the trenches in each alignment mark group indicated by the distance between the single-headed arrows, facing opposite to each other and drawn in alignment mark groups is set to be one fourth of the designed total epitaxial layer thickness at the end of each epitaxial layer growth cycle or longer. | 11-24-2011 |
20120021593 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device includes implanting indium into a first region of a semiconductor substrate; forming a first gate insulation film having a first film thickness in the first region and a second region different from the first region after the implanting; removing the first gate insulation film from the first region; applying heat treatment to the semiconductor substrate after the forming; and forming a second gate insulation film having a second film thickness on the first region after the applying. In the method, a temperature falling rate of the heat treatment in the applying is 20° C. per second or higher. | 01-26-2012 |
20120070969 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - A method for manufacturing a semiconductor device includes steps of preparing a semiconductor substrate having a first conductive type; implanting a first impurity having the first conductive type in the semiconductor substrate to form a well region having a bottom portion; and implanting a second impurity having a second conductive type in the semiconductor substrate to form an impurity region having a top portion, the top of the impurity region being in contact with the bottom portion of the well region. Implantation of the second impurity includes a first step of implanting the second impurity and a second step of implanting the second impurity, wherein a first implantation area of the first step of implanting the second impurity being broader or narrower than a second implantation area of the second step of implanting the second impurity. | 03-22-2012 |
20120083102 | Integrated Shadow Mask/Carrier for Pattern Ion Implantation - An improved, lower cost method of processing substrates, such as to create solar cells is disclosed. In addition, a modified substrate carrier is disclosed. The carriers typically used to carry the substrates are modified so as to serve as shadow masks for a patterned implant. In some embodiments, various patterns can be created using the carriers such that different process steps can be performed on the substrate by changing the carrier or the position with the carrier. In addition, since the alignment of the substrate to the carrier is critical, the carrier may contain alignment features to insure that the substrate is positioned properly on the carrier. In some embodiments, gravity is used to hold the substrate on the carrier, and therefore, the ions are directed so that the ion beam travels upward toward the bottom side of the carrier. | 04-05-2012 |
20120100703 | ION IMPLANTATION SYSTEM AND ION IMPLANTATION METHOD USING THE SAME - According to the present invention, an ion implantation system capable of implanting ions into a large substrate and reducing a manufacturing cost, and an ion implantation method using the same may be provided. The ion implantation system includes a plurality of ion implantation assemblies arranged in a line, each ion implantation assembly to implant ions into a partial region of the substrate. This allows for a compact ion implantation system to implant ions into a very large substrate. The substrate moves through the ion implantation system in a first direction, turns around, and then moves back through the ion implantation system in a second and opposite direction, where ions are implanted into the substrate while the substrate is moving to in both directions. The path in the first direction can be spaced-apart from the path in the second direction to allow for two substrates to be processed simultaneously. | 04-26-2012 |
20120190183 | USING MULTIPLE MASKS TO FORM INDEPENDENT FEATURES ON A WORKPIECE - A first species is directed through a first mask with a first aperture and a second mask with a second aperture. The first aperture and second aperture may be different shapes or have different spacing. The first species may be implanted in pattern defining non-implanted regions surrounded by implanted regions. These implanted regions are a sum of said first ion species implanted through said first aperture and said second aperture. Thus, the non-implanted regions are surrounded by the implanted regions formed using the first mask and second mask. The first species also may deposit on or etch the workpiece. | 07-26-2012 |
20120196428 | ION IMPLANTATION METHOD AND ION IMPLANTATION APPARATUS - In an ion implantation method, ion implantation into a substrate is performed while changing a relative positional relation between an ion beam and the substrate. A first ion implantation process in which a uniform dose amount distribution is formed within the substrate and a second ion implantation process in which a non-uniform dose amount distribution is formed within the substrate are performed in a predetermined order. Moreover, a cross-sectional size of an ion beam irradiated on the substrate during the second ion implantation process is set smaller than a cross-sectional size of an ion beam irradiated on the substrate during the first ion implantation process. | 08-02-2012 |
20120196429 | METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE - A method of manufacturing a semiconductor device that includes a semiconductor substrate is provided. The method includes: exposing a photoresist coated on the semiconductor substrate using a photomask including a plurality of regions having different light transmittances; developing the photoresist to form a resist pattern including a plurality of regions having different thicknesses that depend on an exposure amount of the photoresist; and implanting impurity ions into the semiconductor substrate through the plurality of regions of the resist pattern having different thicknesses to form a plurality of impurity regions whose depths from a surface of the semiconductor substrate to peak positions are different from each other. The depths to the peak positions depend on the thickness of the resist pattern through which the implanted impurity ions pass. | 08-02-2012 |
20120196430 | STEPPED MASKING FOR PATTERNED IMPLANTATION - An improved method of moving a mask to perform a pattern implant of a substrate is disclosed. The mask has a plurality of apertures, and is placed between the ion source and the substrate. After the substrate is exposed to the ion beam, the mask is indexed to a new position relative to the substrate and a subsequent implant step is performed. Through the selection of the aperture size and shape, the index distance and the number of implant steps, a variety of implant patterns may be created. In some embodiments, the implant pattern includes heavily doped horizontal stripes with lighter doped regions between the stripes. In some embodiments, the implant pattern includes a grid of heavily doped regions. In other embodiments, the implant pattern is suitable for use with a bus-bar structure. | 08-02-2012 |
20120295430 | METHOD FOR PROCESSING A SUBSTRATE HAVING A NON-PLANAR SUBSTRATE SURFACE - A technique for conformal processing of a substrate having a non-planar surface is disclosed. The technique includes several stages. In a first stage, some surfaces of the substrate are effectively processed. During a second stage, these surfaces are treated to limit or eliminate further processing of these surfaces. During a third stage, other surfaces of the substrate are processed. In some applications, the surfaces that are perpendicular, or substantially perpendicular to the flow of particles are processed in the first and second stages, while other surfaces are processed in the third stage. In some embodiments, the second stage includes the deposition of a film on the substrate. | 11-22-2012 |
20120309180 | METHOD OF FORMING A RETROGRADE MATERIAL PROFILE USING ION IMPLANTATION - A method of forming a retrograde material profile in a substrate includes forming a surface peak profile on the substrate. Ions are then implanted into the substrate to form a retrograde profile from the surface peak profile, at least one of an ion implantation dose and an ion implantation energy of the implanted ions being chosen so that the retrograde profile has a peak concentration that is positioned at a desired distance from the surface of the substrate. | 12-06-2012 |
20130017675 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A through portion is formed on a semiconductor substrate. Into the semiconductor substrate, a first ion implantation is performed via the through portion. The through portion is at least partially removed in the thickness direction from a region of at least a portion of the through portion when viewed in a plan view. A second ion implantation is performed into the semiconductor substrate at the region of at least the portion thereof. An implantation energy for the first ion implantation is equal to an implantation energy for the second ion implantation. | 01-17-2013 |
20130052813 | METHOD AND STRUCTURE FOR ADVANCED SEMICONDUCTOR CHANNEL SUBSTRATE MATERIALS - Provided is a method and structure for utilizing advance channel substrate materials in semiconductor manufacturing. Advanced channel substrate materials such as germanium and Group III-V channel substrate materials, are advantageously utilized. One or more capping films including at least a nitride layer are formed over the channel substrate prior to patterning, ion implantation and the subsequent stripping and wet cleaning operations. With the capping layers intact during these operations, attack of the channel substrate material is prevented and the protective films are easily removed subsequently. The films are dimensioned in conjunction with the ion implantation operation to enable the desired dopant profile and concentration to be formed in the channel substrate material. | 02-28-2013 |
20130178051 | Method of Impurity Introduction and Controlled Surface Removal - A method of introducing dopants into a semiconductor wafer includes implanting the dopants into a region below a surface of the semiconductor wafer using an ion beam to form a first implanted layer. The dopants when activated causing a conductivity of the implanted layer to be either of N-type or P-type. The first implanted layer is characterized by a peak dopant concentration at a first depth below the surface of the semiconductor wafer. The method also includes removing a layer from the semiconductor wafer surface, wherein said layer includes a portion of said dopants. | 07-11-2013 |
20130196492 | ION IMPLANTATION METHOD AND ION IMPLANTATION APPARATUS - On a plane of a semiconductor wafer, two types of in-plane regions comprising full-width non-ion-implantation regions and partial ion implantation regions, which are alternately arranged one or more times in a direction orthogonal to a scanning direction of an ion beam are created. During the creation of the partial ion implantation regions, reciprocating scanning using the ion beam can be repeated until the target dose can be satisfied while performing or stopping ion beam radiation onto the semiconductor wafer in a state in which the semiconductor wafer can be fixed. During the creation of the full-width non-ion-implantation regions, the semiconductor wafer can be moved without performing the ion beam radiation onto the semiconductor wafer. Then, by repeating fixing and movement of the semiconductor wafer plural times, ion implantation regions and non-ion-implantation regions are created in desired regions of the semiconductor wafer. | 08-01-2013 |
20130224938 | PASSIVATION LAYER FOR WORKPIECES FORMED FROM A POLYMER - Methods of forming a passivation layer on a workpiece are disclosed. These methods utilize a SiC forming polymer to form the passivation layer. In addition, while the polymer is being heated to form SiC, a second result, such as annealing of the underlying workpiece, or firing of the metal contacts is achieved. For example, the workpiece may be implanted prior to coating it with the polymer. When the workpiece is heated, SiC is formed and the workpiece is annealed. In another embodiment, a workpiece is coating with the SiC forming polymer and metal pattern is applied to the polymer. The firing of workpiece causes the metal contacts to form and also forms SiC on the workpiece. | 08-29-2013 |
20130244411 | DIODES WITH A DOG BONE OR CAP-SHAPED JUNCTION PROFILE TO ENHANCE ESD PERFORMANCE, AND OTHER SUBSTRUCTURES, INTEGRATED CIRCUITS AND PROCESSES OF MANUFACTURE AND TESTING - An integrated circuit structure includes a semiconductor doped area (NWell) having a first conductivity type, and a layer (PSD) that overlies a portion of said doped area (NWell) and has a doping of an opposite second type of conductivity that is opposite from the first conductivity type of said doped area (NWell), and said layer (PSD) having a corner in cross-section, and the doping of said doped area (NWell) forming a junction beneath said layer (PSD) with the doping of said doped area (NWell) diluted in a vicinity below the corner of said layer (PSD). Other integrated circuits, substructures, devices, processes of manufacturing, and processes of testing are also disclosed. | 09-19-2013 |
20130260544 | TECHNIQUE FOR PROCESSING A SUBSTRATE - Techniques for processing a substrate are disclosed. In one exemplary embodiment, the technique may be realized as a method for processing a substrate, the method comprising: ionizing first material and second material in an ion source chamber of an ion source, the first material being boron (B) containing material, the second material being one of phosphorous (P) containing material and arsenic (As) containing material; generating first ions containing B and second ions containing one of P and As; and extracting the first and second ions from the ion source chamber and directing the first and second ions toward the substrate. | 10-03-2013 |
20130267083 | PRODUCING METHOD FOR SEMICONDUCTOR DEVICE - According to one embodiment, a producing method for a semiconductor device includes first impurities containing phosphorus or boron in the form of molecular ion and second impurities containing carbon, fluorine or nitrogen with less implantation amount than this phosphorus or boron in the form of molecular ion are implanted into a semiconductor layer to form an impurity implantation layer. | 10-10-2013 |
20130280897 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - A semiconductor device includes a MOS transistor, a source electrode and a drain electrode on the MOS transistor each include a first carbon doped silicon layer including carbon at a first carbon concentration and phosphorus at a first phosphorus concentration and a second carbon doped silicon layer over the first silicon carbide layer, which includes phosphorus at a second phosphorus concentration higher than the first phosphorus concentration, and which includes carbon at a second carbon concentration less than or equal to the first carbon concentration. | 10-24-2013 |
20130288469 | METHODS AND APPARATUS FOR IMPLANTING A DOPANT MATERIAL - Methods and apparatus for implanting a dopant material are provided herein. In some embodiments, a method of processing a substrate disposed within a process chamber may include (a) implanting a dopant material into a surface of the substrate to form a doped layer in the substrate and an elemental dopant layer atop the doped layer; (b) removing at least some of the elemental dopant layer from atop the surface of the substrate; and (c) implanting the dopant material into the doped layer of the substrate; wherein (a)-(c) are performed without removing the substrate from the process chamber; and wherein (a)-(c) are repeated until at least one of a desired dopant implantation depth or a desired dopant implantation density is achieved. | 10-31-2013 |
20130316523 | METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE - A method of manufacturing a semiconductor device having a twin well structure is provided. The method includes ion-implanting of a first conductivity type impurity in a first region and a second region of a semiconductor substrate, the first and second regions being located adjacent to each other; forming a first resist pattern to cover the first region of the semiconductor substrate and to expose the second region of the semiconductor substrate; ion-implanting of a second conductivity type impurity at a higher concentration compared to the first conductivity type impurity in the second region of the semiconductor substrate, with the first resist pattern being used as a mask; and thermal-diffusing the first conductivity type of impurity and the second conductivity type of impurity. | 11-28-2013 |
20130323917 | SELF-ALIGNED PATTERNING FOR DEEP IMPLANTATION IN A SEMICONDUCTOR STRUCTURE - Methods of forming self-aligned patterns for performing oppositely doped deep implantations in a semiconductor substrate are disclosed. The semiconductor substrate has implantation and non-implantation regions. The methods include forming a hardmask pattern for a first implantation with a first conductivity-type dopant, depositing an etch stop layer, filling trenches between the hardmask pattern with a sacrificial filler material having a higher wet etch resistance than the hardmask, removing a top portion of the sacrificial filler material and the etch stop layer over a top surface of the hardmask pattern, removing the hardmask pattern in the implantation region by wet etching, and performing a second ion implantation with a second conductivity type dopant opposite of the first conductivity type. | 12-05-2013 |
20140004688 | ION IMPLANTATION METHOD AND ION IMPLANTATION APPARATUS | 01-02-2014 |
20140065807 | PARTIALLY-BLOCKED WELL IMPLANT TO IMPROVE DIODE IDEALITY WITH SiGe ANODE - A method of manufacturing a semiconductor device is disclosed. A p-type substrate is doped to form an N-well in a selected portion of a p-type substrate adjacent an anode region of the substrate. A p-type doped region is formed in the anode region of the p-type substrate. The p-type doped region and the N-well form a p-n junction. | 03-06-2014 |
20140106550 | ION IMPLANTATION TUNING TO ACHIEVE SIMULTANEOUS MULTIPLE IMPLANT ENERGIES - A method of ion implantation is disclosed. A beam of ions is accelerated to a first energy level. The beam of ions is decelerated from the first energy level to produce a contamination beam of ions via an ion collision process. The ions of the contamination beam are implanted in a substrate to obtain a selected dopant profile in the substrate. | 04-17-2014 |
20140377941 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE - When forming a p+ area and n+ area on the same surface of an n− semiconductor wafer, a first ion implantation forms the p+ area on the entire rear surface of the n− semiconductor wafer. Next, a resist mask selectively covering the rear surface of the n− semiconductor wafer is formed. With this resist mask as the mask, an n-type impurity is injected into the rear surface of the n− semiconductor wafer through a second ion implantation to form the n+ area on a portion deeper from the rear surface of the n− semiconductor wafer than the p+ type area. Thereafter, the n− semiconductor wafer is exposed to an oxygen (O | 12-25-2014 |
20150099351 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE - A method for fabricating a semiconductor device is provided. An ion implantation mask exposing a portion of a semiconductor substrate is formed on the semiconductor substrate. The implantation mask includes a second hardmask layer having a first thickness and a second hardmask layer having a second thickness. The first hardmask layer is disposed between the second hardmask layer and the semiconductor substrate. An ion implantation process is performed on the exposed portion of the semiconductor substrate using the implantation mask. The implantation mask is removed without forming an etch mask layer on the exposed portion of the semiconductor substrate. | 04-09-2015 |
20150294859 | PHOTORESIST FILM PLACING METHOD, SEMICONDUCTOR DEVICE MANUFACTURING METHOD, ELECTRO-OPTICAL DEVICE, AND ELECTRONIC DEVICE - A method for placing a resist film of a region having a small film thickness with good shape accuracy is provided. The method has processes of placing a photoresist film | 10-15-2015 |
20150325674 | Methods of Fabricating Diodes with Multiple Junctions - An embodiment of a method of fabricating a diode having a plurality of regions of a first conductivity type and a buried region of a second conductivity type includes performing a first dopant implantation procedure to form the buried region, performing a second dopant implantation procedure to form an intermediate region of the plurality of regions, and performing a third dopant implantation procedure to form a contact region of the plurality of regions. The second and third dopant implantation procedures are configured such that the intermediate region is electrically connected with the contact region. The first, second, and third dopant implantation procedures are configured such that the buried region extends laterally across the contact region and the intermediate region to establish first and second junctions of the diode, respectively, and such that the first junction has a lower breakdown voltage than the second junction. | 11-12-2015 |
20160148809 | FORMATION OF ISOLATION SURROUNDING WELL IMPLANTATION - Embodiments of present invention provide a method of making well isolations. The method includes forming a hard-mask layer on top of said substrate; forming a first resist-mask on top of a first portion of the hard-mask layer and applying the first resist-mask in forming a first type of wells in a first region of the substrate; forming a second resist-mask on top of a second portion of the hard-mask layer and applying the second resist-mask in forming a second type of wells in a second region of the substrate; applying the first and second resist-masks in transforming the hard-mask layer into a hard-mask, the hard-mask having openings aligned to areas overlapped by the first and second regions of the substrate; etching at least the areas of the substrate in creating deep trenches that separate the first and second types of wells; and filling the deep trenches with insulating materials. | 05-26-2016 |
438528000 | Providing nondopant ion (e.g., proton, etc.) | 4 |
20080200017 | Method of producing semiconductor device - A method of producing a semiconductor device includes the steps of: introducing a p-type impurity corresponding to a conductive type of a channel area into a channel forming area; introducing fluorine into the channel forming area at a low acceleration voltage; and thermally processing a substrate to increase a threshold voltage. In the method of the present invention, the step of thermally processing the substrate is performed after the steps of introducing the p-type impurity into the channel forming area and introducing fluorine into the channel forming area. Further, the steps of introducing the p-type impurity into the channel forming area and introducing fluorine into the channel forming area may be performed any order. | 08-21-2008 |
20090035924 | METHOD OF FORMING A SEMICONDUCTOR STRUCTURE COMPRISING AN IMPLANTATION OF IONS OF A NON-DOPING ELEMENT - A method of forming a semiconductor structure includes providing a substrate having a first feature and a second feature. A mask is formed over the substrate. The mask covers the first feature. An ion implantation process is performed to introduce ions of a non-doping element into the second feature. The mask is adapted to absorb ions impinging on the first feature. After the ion implantation process, an annealing process is performed. | 02-05-2009 |
20090061606 | METHOD FOR REDUCING DISLOCATION THREADING USING A SUPPRESSION IMPLANT - The present invention provides a method for manufacturing a semiconductor device. In one embodiment, the method for manufacturing the semiconductor device includes a method for manufacturing a zener diode, including among others, forming a doped well ( | 03-05-2009 |
20150064890 | METHOD FOR PRODUCING A SEMICONDUCTOR - A method for producing a semiconductor is disclosed, the method having: providing a semiconductor body having a first side and a second side; forming an n-doped zone in the semiconductor body by a first implantation into the semiconductor body via the first side to a first depth location of the semiconductor body; and forming a p-doped zone in the semiconductor body by a second implantation into the semiconductor body via the second side to a second depth location of the semiconductor body, a pn-junction forming between said n-doped zone and said p-doped zone in the semiconductor body. | 03-05-2015 |
438529000 | Using same conductivity-type dopant | 8 |
20080261386 | SAMPLE WAFER FABRICATION METHOD - A third channel region into which a high concentration N-type impurity is implanted, a fourth channel region into which a low concentration N-type impurity is implanted, a first channel region into which a high concentration P-type impurity is implanted, and a second channel region into which a low concentration P-type impurity is implanted are formed in predetermined regions on a wafer. A first region where the second channel region and the third channel region are formed, a second region where the second channel region and the forth channel region are formed, a third region where the first channel region and the third channel region are formed, and a fourth region where the first channel region and the forth channel region are formed are thereby formed. | 10-23-2008 |
20090291548 | METHOD FOR PREPARING P-TYPE POLYSILICON GATE STRUCTURE - A method for preparing a P-type polysilicon gate structure comprises the steps of forming a gate oxide layer on a substrate, forming an N-type polysilicon layer on the gate oxide layer, performing a first implanting process to convert the N-type polysilicon layer into a P-type polysilicon layer, performing a second implanting process to implant P-type dopants into a portion of the P-type polysilicon layer near the interface between the gate oxide layer and the P-type polysilicon layer, and performing a thermal treating process at a predetermined temperature for a predetermined period to complete the P-type polysilicon gate structure. | 11-26-2009 |
20110201187 | IGBT AND METHOD FOR MANUFACTURING IGBT - A vertical IGBT includes a floating region of the first conductive type being formed within the body region of the second conductive type. A density of first conductive type impurities at a boundary of the floating region and the body region that is above the floating region is distributed to increase from an upper side to a lower side. A density of the first conductive type impurities at a boundary of the floating region and the body region that is under the floating region is distributed to decrease from an upper side to a lower side. A density of second conductive type impurities at a boundary of the floating region and the body region that is above the floating region is distributed to decrease from an upper side to a lower side. A density of the second conductive type impurities at a boundary of the floating region and the body region that is under the floating region is distributed to increase from an upper side to a lower side. | 08-18-2011 |
20110256698 | STEPPED MASKING FOR PATTERNED IMPLANTATION - An improved method of moving a mask to perform a pattern implant of a substrate is disclosed. The mask has a plurality of apertures, and is placed between the ion source and the substrate. After the substrate is exposed to the ion beam, the mask is indexed to a new position relative to the substrate and a subsequent implant step is performed. Through the selection of the aperture size and shape, the index distance and the number of implant steps, a variety of implant patterns may be created. In some embodiments, the implant pattern includes heavily doped horizontal stripes with lighter doped regions between the stripes. In some embodiments, the implant pattern includes a grid of heavily doped regions. In other embodiments, the implant pattern is suitable for use with a bus-bar structure. | 10-20-2011 |
20120135587 | N-type carrier enhancement in semiconductors - A method for generating n-type carriers in a semiconductor is disclosed. The method includes supplying a semiconductor having an atomic radius. Implanting an n-type dopant species into the semiconductor, which n-type dopant species has a dopant atomic radius. Implanting a compensating species into the semiconductor, which compensating species has a compensating atomic radius. Selecting the n-type dopant species and the compensating species in such manner that the size of the semiconductor atomic radius is inbetween the dopant atomic radius and the compensating atomic radius. A further method is disclosed for generating n-type carriers in germanium (Ge). The method includes setting a target concentration for the carriers, implanting a dose of an n-type dopant species into the Ge, and selecting the dose to correspond to a fraction of the target carrier concentration. Thermal annealing the Ge in such manner as to activate the n-type dopant species and to repair a least a portion of the implantation damage. Repeating the implantation and the thermal annealing until the target n-type carrier concentration has been reached. | 05-31-2012 |
20140162442 | METHOD OF REDUCING CONTACT RESISTANCE - In one embodiment a method of forming low contact resistance in a substrate includes forming a silicide layer on the substrate, the silicide layer and substrate defining an interface therebetween in a source/drain region, and performing a hot implant of a dopant species into the silicide layer while the substrate is at a substrate temperature greater than 150° C., where the hot implant is effective to generate an activated dopant layer containing the dopant species, and the activated dopant layer extends from the interface into the source/drain region. | 06-12-2014 |
20140187026 | Method of Manufacture of an Optoelectronic Device and an Optoelectronic Device Manufactured Using the Method - A method of manufacture of an optoelectronic device includes the steps of: providing or forming a body of crystalline silicon containing substitutional carbon atoms, and irradiating said body of crystalline silicon with protons (H | 07-03-2014 |
20140377942 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device suppresses loss of vacuum in a chamber of an ion implanter, sag of a resist mask pattern for ion implantation, and producing a resist residue after ashing. First ion implanting process implants n-type impurity to form n | 12-25-2014 |