Abstract: A packaged UV-LED device comprises a die carrier member having a cup-shaped recess, a fused silica lens member that is anodic bonded to the die carrier member, and a UV-LED die that is flip-chip mounted within a sealed cavity formed by the carrier member and the lens member. The carrier member involves a unitary cup member fashioned in an economical way from monocrystalline silicon wafer material. A dielectric/aluminum reflector that is effective for UV radiation and that does not degrade and overheat is disposed on the sidewalls of the recess. The lens member is anodic bonded to a silicon surface of the rim of this unitary cup member at a time when the UV-LED die is disposed in the recess. The anodic bonding is done in such way that the die is not damaged and such that the entire packaged UV-LED device includes no UV-degradable adhesive.

Abstract: Methods of fabricating nano-scale structures are provided. A method includes forming a first hard mask pattern corresponding to first openings in a dense region, forming first guide elements on the first hard mask pattern aligned with the first openings, and forming second hard mask patterns in a sparse region to provide isolated patterns. A blocking layer is formed in the sparse region to cover the second hard mask patterns. A first domain and second domains are formed in the dense region using a phase separation of a block co-polymer layer. Related nano-scale structures are also provided.

Abstract: Provided is a TFT substrate (10) on which vapor-deposited sections are to be formed by use of a vapor deposition device (50) which includes a vapor deposition source (85) having injection holes (86); and a vapor deposition mask (81) having opening (82) through which vapor deposition particles are deposited to form the vapor-deposited sections. The TFT substrate (10) includes pixels two-dimensionally arranged in a pixel region (AG); and wires (14) electrically connected to the respective pixels. The vapor-deposited sections (Q) are formed with gaps (X) therebetween, and the wires (14) having respective terminals that are disposed in the gaps (X).

Abstract: The present disclosure provides a method for fabricating a high-voltage semiconductor device. The method includes designating first, second, and third regions in a substrate. The first and second regions are regions where a source and a drain of the semiconductor device will be formed, respectively. The third region separates the first and second regions. The method further includes forming a slotted implant mask layer at least partially over the third region. The method also includes implanting dopants into the first, second, and third regions. The slotted implant mask layer protects portions of the third region therebelow during the implanting. The method further includes annealing the substrate in a manner to cause diffusion of the dopants in the third region.

Abstract: In one embodiment, a method includes forming a base region for a transistor using a base mask and forming a contact region to the base region. The contact region is formed in an area that is at least partially outside of the base mask. The method then forms an emitter region in a diffused base region. The base region diffuses outwardly to be formed under the contact region.

Abstract: A method of manufacturing doping patterns includes providing a substrate having a plurality of STIs defining and electrically isolating a plurality of active regions in the substrate, forming a patterned photoresist having a plurality of exposing regions for exposing the active regions and the STIs in between the active regions on the substrate, and performing an ion implantation to form a plurality of doping patterns in the active regions.

Abstract: The present invention provides a method (80) for manufacturing a semiconductor tip. The method comprises obtaining (81) a substrate provided with a layer of tip material, providing (82) a doping profile in the layer of tip material, the doping profile comprising a tapered-shaped region of a first dopant concentration, undoped or lightly doped, e.g. having a dopant concentration of 1017 cm?3 or lower, surrounded by a region of a second dopant concentration, highly doped, e.g. having a dopant concentration above 1017 cm?3, the first dopant concentration being lower than the second dopant concentration, and isotropically etching (83) the layer of tip material by using an etch chemistry for which the etch rate of tip material with the second dopant concentration is substantially higher than the etch rate of the tip material with the first dopant concentration.

Abstract: A method of increasing etch rate during deep silicon dry etch by altering the geometric shape of the etch mask is presented. By slightly altering the shape of the etch mask, the etch rate is increased in one area where an oval etch mask is used as compared to another areas where different geometrically-shaped etch masks are used even though nearly the same amount of silicon is exposed. Additionally, the depth of the via can be controlled by using different geometrically-shaped etch masks while maintaining virtually the same size in diameter for all the vias.

Abstract: A memory device includes a number of memory cells and a number of bit lines. Each of the bit lines includes a first region having a first width and a first depth and a second region having a second width and a second depth, where the first width is less than the second width. The first region may include an n-type impurity and the second region may include a p-type impurity.

Abstract: A method of forming a semiconductor device having an active area and a termination area surrounding the active area comprises providing a semiconductor substrate, providing a semiconductor layer of a first conductivity type over the semiconductor substrate and forming a mask layer over the semiconductor layer. The mask layer outlines at least two portions of a surface of the semiconductor layer: a first outlined portion outlining a floating region in the active area and a second outlined portion outlining a termination region in the termination area. Semiconductor material of a second conductivity type is provided to the first and second outlined portions so as to provide a floating region of the second conductivity type buried in the semiconductor layer in the active area and a first termination region of the second conductivity type buried in the semiconductor layer in the termination area of the semiconductor device.

Abstract: A semiconductor structure is provided that includes a plurality of vertically stacked and vertically spaced apart semiconductor nanowires (e.g., a semiconductor nanowire mesh) located on a surface of a substrate. One end segment of each vertically stacked and vertically spaced apart semiconductor nanowires is connected to a source region and another end segment of each vertically stacked and vertically spaced apart semiconductor nanowires is connected to a drain region. A gate region including a gate dielectric and a gate conductor abuts the plurality of vertically stacked and vertically spaced apart semiconductor nanowires, and the source regions and the drain regions are self-aligned with the gate region.

Abstract: 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.

Abstract: A masking paste used as a mask for controlling diffusion when diffusing a p-type dopant and an n-type dopant into a semiconductor substrate and forming a high-concentration p-doped region and a high concentration n-doped region is provided that contains at least a solvent, a thickening agent, and SiO2 precursor and/or a TiO2 precursor. Further, a manufacturing method of a solar cell is provided in which the masking paste is pattern-formed on the semiconductor substrate and then the p-type dopant and the n-type dopant are diffused.

Abstract: A semiconductor device has a channel termination region for using a trench 30 filled with field oxide 32 and a channel stopper ring 18 which extends from the first major surface 8 through p-well 6 along the outer edge 36 of the trench 30, under the trench and extends passed the inner edge 34 of the trench. This asymmetric channel stopper ring provides an effective termination to the channel 10 which can extend as far as the trench 30.

Abstract: Masked and controlled ion implants, coupled with annealing or etching are used in CVD formed single crystal diamond to create structures for both optical applications, nanoelectromechanical device formation, and medical device formation. Ion implantation is employed to deliver one or more atomic species into and beneath the diamond growth surface in order to form an implanted layer with a peak concentration of atoms at a predetermined depth beneath the diamond growth surface. The composition is heated in a non-oxidizing environment under suitable conditions to cause separation of the diamond proximate the implanted layer. Further ion implants may be used in released structures to straighten or curve them as desired. Boron doping may also be utilized to create conductive diamond structures.

Abstract: A method for forming a semiconductor device includes forming a first dielectric layer over a first portion of a substrate, forming a charge storage layer over the first dielectric layer and etching a trench in the charge storage layer and the first dielectric layer, where the trench extends to the substrate. The method also includes implanting n-type impurities into the substrate to form an n-type region having a first depth and a first width and implanting p-type impurities into the substrate after implanting the n-type impurities, the p-type impurities forming a p-type region having a second depth and a second width. The method further includes forming a second dielectric layer over the charge storage layer and forming a control gate over the second dielectric layer.

Abstract: A structure for reduction of soft error rates in integrated circuits. The structure including: a semiconductor substrate; and a stack of one or more wiring levels stacked from a lowermost wiring level to an uppermost wiring level, the lowermost wiring level nearer the semiconductor substrate than the uppermost wiring level; and an alpha particle blocking layer on a top surface of the uppermost wiring level of the one or more wiring levels, the blocking layer comprising metal wires and a dielectric material, the blocking layer having a combination of a thickness of the blocking layer and a volume percent of metal wires in the blocking layer sufficient to stop a predetermined percentage of alpha particles of a selected energy or less striking the blocking layer from penetrating into the stack of one or more wiring levels or the substrate.

Abstract: The method for manufacturing the indium gallium aluminium nitride (InGaAlN) thin film on silicon substrate, which comprises the following steps: introducing magnesium metal for processing online region mask film, that is, or forming one magnesium mask film layer or metal transition layer; then forming one metal transition layer or magnesium mask layer, finally forming one layer of indium gallium aluminium nitride semiconductor layer; or firstly forming one layer of metal transition layer on silicon substrate and then forming the first indium gallium aluminium nitride semiconductor layer, magnesium mask layer and second indium gallium aluminium nitride semiconductor layer in this order. This invention can reduce the dislocation density of indium gallium aluminium nitride materials and improve crystal quality.

Abstract: A method for reduction of soft error rates in integrated circuits. The method including: providing a test device, the test device comprising: a semiconductor substrate; and a stack of one or more wiring levels stacked from a lowermost wiring level to an uppermost wiring level, the lowermost wiring level on a top surface of the substrate; selecting an energy of alpha particles of a given energy to be stopped from penetrating through the stack of one or more wiring levels; bombarding the semiconductor substrate with a flux of the alpha particles of the selected energy; and determining a combination of a thickness of a blocking layer and a volume percent of metal wires in the blocking layer sufficient to stop a predetermined percentage of alpha particles of the maximum energy striking a top surface of the blocking layer from penetrating through the stack of one or more wiring levels.

Abstract: A zener diode and methods for fabricating and packaging same are disclosed, whereby contact hole forming process exposing a diffusion layer is removed to enable to simplify the fabricating process, and the diffusion length not contacting the electrode line is determined by the crosswise length toward which the impurity is diffused to enable to reduce the zener impedance value. Furthermore, wet etching is used following the diffusion to remove the diffusion masks such that no damage is given to the diffusion layers to thereby enable to improve the zener diode characteristics.

Abstract: A method of increasing etch rate during deep silicon dry etch by altering the geometric shape of the etch mask is presented. By slightly altering the shape of the etch mask, the etch rate is increased in one area where an oval etch mask is used as compared to another areas where different geometrically-shaped etch masks are used even though nearly the same amount of silicon is exposed. Additionally, the depth of the via can be controlled by using different geometrically-shaped etch masks while maintaining virtually the same size in diameter for all the vias.

Abstract: Methods for fabricating contacts to semiconductor structures are provided. A method comprises forming two members extending from a semiconductor substrate and separated by a portion of the substrate. First and second semiconductor devices are formed in and on the substrate and each comprise a common impurity doped region that is disposed within the portion of the substrate. A dielectric layer is deposited overlying the members, the semiconductor devices, and the common impurity doped region to a thickness such that a depression overlying the impurity doped region is formed. A fill material is deposited to substantially fill the depression and a portion of the dielectric layer is etched. A masking layer is deposited and a portion of the masking layer is removed to expose the fill material. A via is formed by etching the fill material and dielectric layer and a conductive material is deposited therein.

Abstract: A method of fabricating an electronic device and a resulting electronic device. The method includes forming a pad oxide layer on a substrate, forming a silicon nitride layer over the pad oxide layer, and forming a top oxide layer over the silicon nitride layer. A first dopant region is then formed in a first portion of the substrate. A first portion of the top oxide layer is removed; a remaining portion of the top oxide layer is used to align a second dopant mask and a second dopant region is formed. An annealing step drives-in the dopants but oxygen diffusion to the substrate is limited by the silicon nitride layer; the silicon nitride layer thereby assures that the uppermost surface of the silicon is substantially planar in an area proximate to the dopant regions after the annealing step.

Abstract: A structure and a method for reduction of soft error rates in integrated circuits. The structure including: a semiconductor substrate; and a stack of one or more wiring levels stacked from a lowermost wiring level to an uppermost wiring level, the lowermost wiring level nearer the semiconductor substrate than the uppermost wiring level; and an alpha particle blocking layer on a top surface of the uppermost wiring level of the one or more wiring levels, the blocking layer comprising metal wires and a dielectric material, the blocking layer having a combination of a thickness of the blocking layer and a volume percent of metal wires in the blocking layer sufficient to stop a predetermined percentage of alpha particles of a selected energy or less striking the blocking layer from penetrating into the stack of one or more wiring levels or the substrate.

Abstract: A submount substrate for mounting a light emitting device and a method of fabricating the same, wherein since a submount substrate for mouthing a light emitting device in which a Zener diode device is integrated can be fabricated by means of a silicon bulk micromachining process without using a diffusion mask, some steps of processes related to the diffusion mask can be eliminated to reduce the manufacturing costs, and wherein since a light emitting device can be flip-chip bonded directly to a submount substrate for a light emitting device in which a Zener diode device is integrated, a process of packaging the light emitting device and the voltage regulator device can be simplified.

Abstract: A method is provided for forming a graded junction in a semiconductor material having a first conductivity type. Dopant having a second conductivity type opposite the first conductivity type is introduced into a selected region of the semiconductor material to define a primary dopant region therein. The perimeter of the primary dopant region defines a primary pn junction. While introducing dopant into the selected region of the semiconductor material, dopant is simultaneously introduced into the semiconductor material around the perimeter of the primary dopant region and spaced-apart from the primary pn junction. The dopant in the both the primary dopant region and in the dopant around the perimeter of the primary dopant region is then diffused to provide a graded dopant region.

Abstract: According to a method for producing a solid body (1) including a microstructure (2), the surface of a substrate (3) is provided with a masking layer (6) that is impermeable to a substance to be applied. The substance is then incorporated into the substrate regions not covered by the masking layer (6). A heat treatment is used to diffuse the substance into a substrate region covered by the masking layer (6) such that a concentration gradient of the substance is created in the substrate region covered by the masking layer (6), proceeding from the edge of the masking layer (6) inward with increasing distance from the edge. The masking layer (6) is then removed to expose the substrate region under this layer, and a near-surface layer of the substrate (3) in the exposed substrate region is converted by a chemical conversion reaction into a coating (9) which has a layer thickness profile corresponding to the concentration gradient of the substance contained in this near-surface layer.

Abstract: A method of forming bipolar transistors by using the same mask to form the collector region in a substrate of an opposite conductivity type as to form the base in the collector region. More specifically, impurities of a first conductivity type are introduced into a region of a substrate of a second conductivity type through a first aperture in a first mask to form a collector region. Impurities of the second conductivity type are introduced in the collector through the first aperture in the first mask to form the base region. Impurities of the first conductivity type are then introduced into the base region through a second aperture in a second mask to form the emitter region. The minimum dimension of the first aperture of the first mask is selected for a desired collector to base breakdown voltage. This allows tuning of the breakdown voltage.

Abstract: A method for fabricating an RF enhancement mode FET (30) having improved gate properties is provided. The method comprises the steps of providing (131) a substrate (31) having a stack of semiconductor layers (32-35) formed thereon, the stack including a cap layer (35) and a central layer (33) defining a device channel, forming (103) a photoresist pattern (58) over the cap layer, thereby defining a masked region and an unmasked region, and, in any order, (a) creating (105) an implant region (36, 37) in the unmasked region, and (b) removing (107) the cap layer from the unmasked region. By forming the implant region and cap region with no overlap, a device with low current leakage may be achieved.

Abstract: An organic resin with an optical crosslinking agent therein is coated to form an organic resin layer over a resist mast and a patterned thin film, and crosslinked. Although some debris are formed over the resist mask in the fabrication of the patterned thin film, they are trapped by the crosslinked organic resin layer. The resist mask and the organic resin layer are removed through immersion in an organic solvent and vibration therein without flashes.

Abstract: A method for manufacturing an electronic device is provided. In one example of the method, the method prevents deformation of a resist mask caused by the irradiation of exposure light. The resist mask has a resist as an opaque element, and can afford mask patterns undergoing little change even with an increase in the number of wafers subjected to exposure processing. The resist mask maintains a high dimensional accuracy. A photomask pattern is formed using as an opaque element a resist comprising a base resin and Si incorporated therein or a resist with a metal such as Si incorporated thereby by a silylation process, to improve the resistance to active oxygen. The deformation of a resist opaque pattern in a photomask is prevented. The dimensional accuracy of patterns transferred onto a Si wafer is improved in repeated use of the photomask.

Abstract: A method for fabricating an RF enhancement mode FET (30) having improved gate properties is provided. The method comprises the steps of providing (131) a substrate (31) having a stack of semiconductor layers (32-35) formed thereon, the stack including a cap layer (35) and a central layer (33) defining a device channel, forming (103) a photoresist pattern (58) over the cap layer, thereby defining a masked region and an unmasked region, and, in any order, (a) creating (105) an implant region (36, 37) in the unmasked region, and (b) removing (107) the cap layer from the unmasked region. By forming the implant region and cap region with no overlap, a device with low current leakage may be achieved.

Abstract: A novel nickel self-aligned silicide (SALICIDE) process technology (80) adapted for CMOS devices (54) with physical gate lengths of sub-40 nm. The excess silicidation problem (52) due to edge effect is effectively solved by using a low-temperature, in-situ formed Ni-rich silicide, preferably formed in a temperature range of 260-310° C. With this new process, excess poly gate silicidation is prevented. Island diode leakage current and breakdown voltage are also improved.

Abstract: A method for forming an etching mask structure on a substrate includes etching the substrate, laterally expanding the etching mask structure, and depositing a self-aligned metal layer that is aligned to the originally masked area. The etching can be isotropic or anisotropic. The self-aligned metal layer can be distanced from the original etching masked area based on the extent of the intentionally laterally expanded etching mask layer. Following metal deposition, the initial mask structure can be removed, thus lifting off the metal atop it. The etching mask structure can be a resist and can be formed using conventional photolithography materials and techniques and can have nearly vertical sidewalls. The lateral extension can include a silylation technique of the etching mask layer following etching. The above method can be utilized to form bipolar, hetero-bipolar, or field effect transistors.

Abstract: An LED is provided with a p-type semiconductor region in the shape of an island being buried in an n-type semiconductor region from the surface of it, and forms a pn junction at the interface between these n-type region and p-type region. The pn junction has a bottom junction at the bottom of the n-type region and a side junction at the peripheral side face. The bottom junction comprises a first subjunction being deep and constant in junction depth and a second subjunction varying continuously in junction depth. The depth of the second subjunction is shallower than the depth of the first subjunction. The p-type region portion above the second subjunction is thinner in thickness than the p-type region portion above the first subjunction. A light passing through the p-type region portion of the former is less in absorption and more in optical power of the output light. The total power of the output light of the whole LED is increased correspondingly to reduction in thickness of the p-type region.

Abstract: A patterned photoresist layer is coated onto a semiconductor substrate. Then a doped region is formed in the semiconductor substrate not covered by the patterned photoresist layer. In addition, a semiconductor process is performed to trim the patterned photoresist layer, and a lightly doped drain (LDD) region is formed in the region of the semiconductor substrate next to the doped region. The doped region and the LDD region constitute the buried bit lines of the mask ROM. Finally, the photoresist layer is stripped.

Abstract: An exemplary embodiment described in the disclosure relates to a method of fabricating an integrated circuit which includes providing a bulk layer over a semiconductor substrate, providing an imaging layer over the bulk layer, imaging the imaging layer to expose portions of the imaging layer, removing the exposed portions of the imaging layer, etching the bulk layer at locations where exposed portions of the imaging layer were removed to provide at least one aperture in the bulk layer, and silylating the bulk layer.

Abstract: A method for fabricating semiconductor device capable of forming silicide suitable for highly integrated semiconductor device comprising the steps of: forming a conductive oxide layer and metal layer on a substrate having a gate and source/drain regions; performing a first thermal treatment on the resulting structure; selectively removing the metal layer to retain the metal layer over only the part corresponding to the source/drain regions; forming an intermediate phase by etching the conductive oxide layer with the remaining metal layer employed as a mask; and forming a silicide layer by performing a second thermal treatment on the substrate including the intermediate phase.

Abstract: A integrated circuit device and method for manufacturing an integrated circuit device includes forming a patterned gate stack, adjacent a storage device, to include a storage node diffusion region adjacent the storage device and a bitline contact diffusion region opposite the storage node diffusion region, implanting an impurity in the storage node diffusion region and the bitline contact diffusion region, forming an insulator layer over the patterned gate stack, removing a portion of the insulator layer from the bitline contact diffusion region to form sidewall spacers along a portion of the patterned gate stack adjacent the bitline contact diffusion region, implanting a halo implant into the bitline contact diffusion region, wherein the insulator layer is free from blocking the halo implant from the second diffusion region and annealing the integrated circuit device to drive the halo implant ahead of the impurity.

Abstract: A process for fabricating a memory cell in a two-bit EEPROM device, includes forming an ONO layer overlying a semiconductor substrate, depositing a resist mask overlying the ONO layer, patterning the resist mask, implanting the semiconductor substrate with a p-type dopant, wherein the resist mask is used as an ion implant mask, and annealing the semiconductor substrate before implanting the semiconductor substrate with an n-type dopant. In one preferred embodiment, the annealing of the semiconductor substrate laterally diffuses the p-type dopants to form pocket regions on either side of the EEPROM device.

Abstract: A trench-gate semiconductor device, for example a MOSFET or IGBT, of compact geometry is manufactured with self-aligned masking techniques in a simple process with good reproducibility. The source region (13) of the device is formed by introducing dopant (63) into an area of the body region (15) via a mask window (51a), diffusing the dopant to form a surface region (13b) that extends laterally below the mask (51) at a distance (d) beyond the masking edge (51b) of the window (51a), and then etching the body (10) at the window (51a) to form a trench (20) for the trench-gate (11) with a lateral extent (y) that is determined by the etching of the body (10) at the masking edge (51b) of the window (51a). A portion of the surface region (13b) is left to provide the source region (13) adjacent to the trench (20).

Abstract: A method of forming electrical contacts includes the step of implanting ions into a contact hole at an angle to create an enlarged plug enhancement region at the bottom of a contact hole. Thus, even if the contact hole is misaligned, over-sized, or over-etched, the enlarged plug enhancement region contains subsequently formed barrier layers and other conductive materials to reduce current leakage into the underlying substrate or into adjacent circuit elements.

Abstract: A single mask process for manufacture of a FRED employs a thick oxide layer over an N type silicon surface and a thin nitride layer over the oxide. A single mask defines FRED device spaced P diffusions. The oxide spanning the P diffusions is laterally etched away, under the nitride layer to expose the surface of adjacent P diffusions and the spanning N type silicon surface. All nitride is then removed and a top contact layer of aluminum is applied atop the silicon surface, contacting a P guard ring diffusion; the surface of the P diffusions defining PN junctions; and the top of the N silicon to define a Schottky diode contact.

Abstract: A semiconductor processing method of forming a resistor from semiconductive material includes: a) providing a node to which electrical connection to a resistor is to be made; b) providing a first electrically insulative material outwardly of the node; c) providing an exposed vertical sidewall in the first electrically insulative material outwardly of the node; d) providing a second electrically insulative material outwardly of the first material and over the first material vertical sidewall, the first and second materials being selectively etchable relative to one another; e) anisotropically etching the second material selectively relative to the first material to form a substantially vertically extending sidewall spacer over the first material vertical sidewall and to outwardly expose the first material adjacent the sidewall spacer, the spacer having an inner surface and an outer surface; f) etching the first material selectively relative to the second material to outwardly expose at least a portion of the s

Abstract: A method for counter-doping gate stack conductors on a semiconductor substrate, which substrate is provided with narrow space array regions (i.e., memory device regions) having a plurality of capped gate stack conductors spaced a first distance apart, and wide space array regions (i.e., logic device regions) having a plurality of gate stack conductors spaced a second distance apart, wherein the first distance is narrow in relation to the second distance.

Abstract: An element isolation method, in particular, a shallow trench isolation (STI) method for semiconductor devices is disclosed in which a trench is formed to have a stepped structure shaped in such a fashion that it has a smaller width at its lower portion than at its upper portion. This stepped trench structure, which includes at least one step, is capable of obtaining an increased metal contact margin, thereby preventing metal contacts from being short-circuited with wells due to a misalignment thereof.

Abstract: A method used during the formation of a semiconductor device comprises the steps of forming a polycrystalline silicon layer over a semiconductor substrate assembly and forming a silicon nitride layer over the polycrystalline silicon layer. A silicon dioxide layer is formed over the silicon nitride layer and the silicon dioxide and silicon nitride layers are patterned using a patterned mask having a width, thereby forming sidewalls in the two layers. The nitride and oxide layers are subjected to an oxygen plasma which treats the sidewalls and leaves a portion of the silicon nitride layer between the sidewalls untreated. The silicon dioxide and the untreated portion of the silicon nitride layer are removed thereby resulting in pillars of treated silicon nitride. Finally, the polycrystalline silicon is etched using the pillars as a mask. The patterned polycrystalline silicon layer thereby comprises features having widths narrower than the width of the original mask.

Abstract: An integrated circuit fabrication process is provided for using a dual salicidation process to form a silicide gate conductor to a greater thickness than silicide structures formed upon source and drain regions of a transistor. A high K gate dielectric residing between the gate conductor and the substrate substantially inhibits consumption of the junctions during the formation of the silicide gate conductor. In an embodiment, a relatively thick layer of refractory metal is deposited across a transistor arranged upon and within a silicon-based substrate. The transistor includes a polysilicon gate conductor arranged upon a portion of a high K gate dielectric interposed between a pair of source and drain junctions. The refractory metal is heated to convert the polysilicon gate conductor to a silicide gate conductor.

Abstract: A process for manufacturing a TFT without the use of ion implantation is described. Instead, heavily doped layers of amorphous silicon are used as diffusion sources. Two embodiments of the invention are described. In the first embodiment the gate pedestal is deposited first, followed by gate oxide and an amorphous layer of undoped silicon. This is followed by the layer of heavily doped amorphous silicon which is subjected to a relatively low energy laser scan which drives in a small amount of dopant and converts it to N-. After the N+ layer has been patterned and etched to form source and drain electrodes, a second, higher energy, laser scan is given. This brings the source and drain very close to, but not touching, the channel, resulting in an LDD type of structure. In the second embodiment a layer of intrinsic polysilicon is used for the channel. It is covered with a layer of gate oxide and a metallic gate pedestal.

Abstract: A trenched gate MOSFET (metal oxide semiconductor field effect transistor) structure is fabricated via a novel process which includes the step of using a common mask serving the dual role as a mask for the body layer formation and as a mask for trench etching. The common mask defines an patterned oxide layer which includes a plurality of openings at a predetermined distance away from the scribe line of the MOSFET structure. During fabrication, material of the body layer is implanted through the openings of the patterned oxide layer. Thereafter, the implanted material is side-diffused and merged together under a drive-in cycle as one continuous body layer. Using the same patterned oxide layer as a shield, trenches are anisotropically etched in the substrate. The MOSFET structure as formed requires no separate mask for delineating the active body region away from the scribe line, resulting reduction of fabrication steps. The consequential benefits are lower manufacturing costs and higher production yields.