Abstract: A method of forming an integrated circuit is disclosed. A second material layer is formed on a first material layer. A patterned mask layer having a plurality of first features with a first pitch P1 is formed on the second material layer. The second material layer is etched by using the patterned mask layer as a mask to form the first features in the second material layer. The patterned mask layer is trimmed. A plurality of dopants is introduced into the second material layer not covered by the trimmed patterned mask layer. The trimmed patterned mask layer is removed to expose un-doped second material layer. The un-doped second material layer is selectively removed to form a plurality of second features with a second pitch P2. P2 is smaller than P1.

Abstract: One object of the present invention is to provide a method for producing a thick film metal electrode that is able to form a positive-negative reverse type resist, which has a thickness of 7 ?m or more and excellent in-plane uniformity, on the circuit element formed on the silicon carbide substrate, and a method for producing a thick film resist, and the present invention provides a method for producing a thick film resist wherein a first positive-negative reverse type resist having a first viscosity is formed on an upper surface of a circuit element layer which is treated with HMDS, and a second positive-negative reverse type resist having a second viscosity, which is larger than the first viscosity, on the first positive-negative reverse type resist such that a total thickness of the first and second positive-negative reverse type resists constituting a thick film resist be 7 ?m or more.

Abstract: Methods of dicing substrates having a plurality of ICs. A method includes forming a multi-layered mask comprising a first mask material layer soluble in a solvent over the semiconductor substrate and a second mask material layer, insoluble in the solvent, over the first mask material layer. The multi-layered mask is patterned with a laser scribing process to provide a patterned mask with gaps. The patterning exposes regions of the substrate between the ICs. The substrate is then plasma etched through the gaps in the patterned mask to singulate the IC with the second mask material layer protecting the first mask material layer for at least a portion of the plasma etch. The soluble material layer is dissolved subsequent to singulation to remove the multi-layered mask.

Abstract: A method of forming a pattern includes forming a photoresist pattern on a substrate, forming a first material layer on substantially an entire surface of the substrate including the photoresist pattern, heat-treating the substrate including the first material layer and the photoresist pattern, and forming the pattern by removing the photoresist pattern and the portion of the first material layer on the photoresist pattern. A method of manufacturing an array substrate includes forming a pixel region bounded by gate and data lines, and a thin film transistor; an insulating layer is selectively removed to form a passivation layer using a photoresist pattern as an etching mask; a transparent conductive layer is formed on substantially the entire substrate, and the substrate is heat treated. The photoresist pattern and the portion of the transparent conductive layer on the photoresist pattern are removed by a stripping material.

Abstract: A method for fabricating a light emitting diode chip is provided. In the method, a half-tone mask process, a gray-tone mask process or a multi-tone mask process is applied and combined with a lift-off process to further reduce process steps of the light emitting diode chip. In the present invention, some components may also be simultaneously formed by an identical process to reduce the process steps of the light emitting diode chip. Consequently, the fabricating method of the light emitting diode provided in the present invention reduces the cost and time for the fabrication of the light emitting diode.

Abstract: A method for fabricating a light emitting diode chip is provided. In the method, a half-tone mask process, a gray-tone mask process or a multi-tone mask process is applied and combined with a lift-off process to further reduce process steps of the light emitting diode chip. In the present invention, some components may also be simultaneously formed by an identical process to reduce the process steps of the light emitting diode chip. Consequently, the fabricating method of the light emitting diode provided in the present invention reduces the cost and time for the fabrication of the light emitting diode.

Abstract: A method for fabricating a light emitting diode chip is provided. In the method, a half-tone mask process, a gray-tone mask process or a multi-tone mask process is applied and combined with a lift-off process to further reduce process steps of the light emitting diode chip. In the present invention, some components may also be simultaneously formed by an identical process to reduce the process steps of the light emitting diode chip. Consequently, the fabricating method of the light emitting diode provided in the present invention reduces the cost and time for the fabrication of the light emitting diode.

Abstract: A method for fabricating a light emitting diode chip is provided. In the method, a half-tone mask process, a gray-tone mask process or a multi-tone mask process is applied and combined with a lift-off process to further reduce process steps of the light emitting diode chip. In the present invention, some components may also be simultaneously formed by an identical process to reduce the process steps of the light emitting diode chip. Consequently, the fabricating method of the light emitting diode provided in the present invention reduces the cost and time for the fabrication of the light emitting diode.

Abstract: A method for fabricating a light emitting diode chip is provided. In the method, a half-tone mask process, a gray-tone mask process or a multi-tone mask process is applied and combined with a lift-off process to further reduce process steps of the light emitting diode chip. In the present invention, some components may also be simultaneously formed by an identical process to reduce the process steps of the light emitting diode chip. Consequently, the fabricating method of the light emitting diode provided in the present invention reduces the cost and time for the fabrication of the light emitting diode.

Abstract: A method for forming a laser diode structure. The method includes providing a laser diode material having a surface region. A multilayer dielectric mask structure comprising alternating first and second dielectric layers is formed overlying the surface region. The method forms a laser diode structure using the multilayer dielectric mask structure as a mask. The method selectively removes a portion of the first dielectric layer to form one or more undercut regions between the second dielectric layers. A passivation layer overlies the multilayer dielectric mask structure and the undercut region remained intact. The dielectric mask structure is selectively removed, exposing a top surface region of the laser diode structure. A contact structure is formed overlying at least the exposed top surface region.

Abstract: A method for fabricating a semiconductor device includes the steps of (a) forming a plasma of a gas having carbon and fluorine, and forming an internal insulation film provided with a fluorine-doped carbon film formed on a substrate using the plasma; (b) forming a metal film on the internal insulation film; (c) etching the metal film according to a pattern to form a hard mask; (d) forming a concave part in the fluorine-doped carbon film by etching the fluorine-doped carbon film using the hard mask; (e) forming a film formation of a wiring material on the substrate for filling the concave part with the wiring material; (f) removing an excess part of the wiring material and the hard mask on the fluorine-doped carbon film for exposing a surface of the fluorine-doped carbon film; and (g) removing an oxide formed on the surface of the fluorine-doped film.

Abstract: A production method for a semiconductor device includes providing a semiconductor substrate having semiconductor layer of a first conductivity type formed on a surface thereof; forming a first mask so as to cover a predetermined region of the semiconductor layer; (c) forming a well region of a second conductivity type by implanting impurity ions of the second conductivity type into the semiconductor layer having the first mask formed thereon; reducing the thickness of the first mask by removing a portion of the first mask; forming a second mask covering a portion of the well region by using photolithography; and forming a source region of the first conductivity type by implanting impurity ions of the first conductivity type into the semiconductor layer having the first mask with the reduced thickness and the second mask formed thereon.

Abstract: A method for fabricating a light emitting diode chip is provided. In the method, a half-tone mask process, a gray-tone mask process or a multi-tone mask process is applied and combined with a lift-off process to further reduce process steps of the light emitting diode chip. In the present invention, some components may also be simultaneously formed by an identical process to reduce the process steps of the light emitting diode chip. Consequently, the fabricating method of the light emitting diode provided in the present invention reduces the cost and time for the fabrication of the light emitting diode.

Abstract: A method of manufacturing a thin film transistor (“TFT”) array panel includes forming a first conductive layer, gate insulating layer, and first insulating layer on a substrate, patterning the first insulating layer to form a first insulating pattern including an opening, etching the gate insulating layer and first conductive layer to form a gate insulating member and a gate line, forming an organic semiconductor in the opening, forming a passivation layer and a second insulating pattern thereon, patterning the second insulating layer to form a second insulating pattern, etching the passivation layer, depositing a second conductive layer thereon, forming a pixel electrode by removing the second insulating pattern and the second conductive layer deposited on the second insulating pattern, and forming a drain electrode and a data line by depositing and patterning a third conductive layer on the resultant structure.

Abstract: A semiconductor device has: a semiconductor substrate having a pair of current input/output regions via which current flows; an insulating film formed on the semiconductor substrate and having a gate electrode opening; and a mushroom gate electrode structure formed on the semiconductor substrate via the gate electrode opening, the mushroom gate electrode structure having a stem and a head formed on the stem, the stem having a limited size on the semiconductor substrate along a current direction and having a forward taper shape upwardly and monotonically increasing the size along the current direction, the head having a size expanded stepwise along the current direction, and the stem contacting the semiconductor substrate in the gate electrode opening and riding the insulating film near at a position of at least one of opposite ends of the stem along the current direction.

Abstract: A thin-film transistor (“TFT”) substrate and a method of fabricating the same include: an insulating substrate; gate wiring which is disposed on the insulating substrate and includes a gate line and a gate electrode; a semiconductor pattern which is disposed on the gate electrode; data wiring which is disposed on the semiconductor pattern and includes a data line, a source electrode, and a drain electrode; a passivation layer which includes a first sub-passivation layer and a second sub-passivation layer deposited on the data wiring; and a pixel electrode which is electrically connected to the drain electrode through a contact hole disposed in the passivation layer, wherein the second sub-passivation layer has a lower density than the first sub-passivation layer.

Abstract: Systems and methods for MEMS device fabrication. A layer of photoresist is formed on a substrate. A first region of the substrate is exposed to a radiation source through a photomask. The first region of exposed photoresist is developed with a developer solution in order to etch the exposed regions to a first depth. A second region is exposed to radiation through a second photomask. The second photomask defines areas in which a bump feature is intended on the substrate. The second region is developed with the developer solution, preparing the first and second exposed regions for a layer of metal. A layer of metal is deposited on the substrate, such that the metal attaches to both the substrate and any remaining photoresist on the substrate. The remaining photoresist and its attached metal is dissolved away leaving an interconnect pattern and at least one bump feature.

Abstract: A semiconductor device is provided. The semiconductor device includes a semiconductor substrate including a conducting layer, a first insulating film formed on the semiconductor substrate and having a via hole formed therein, a lower barrier film formed on an inside wall of the via hole, a first metal wiring formed on the lower barrier film, a second insulating film formed on the first metal wiring and the first insulating film, the second insulating film being provided with a trench which has a width greater than a width of the via hole, an upper barrier film formed on a lower surface of the trench, a second metal wiring formed on the upper barrier film, and a sidewall barrier film formed on sidewalls of the upper barrier film and the second metal wiring. The sidewall barrier film has an L-shaped mirror-symmetrical structure.

Abstract: A method for manufacturing a liquid crystal display includes simultaneously forming a gate electrode and a gate bus line on a transparent dielectric substrate, simultaneously forming a channel layer, an ohmic contact layer, and source/drain electrodes by forming a gate insulation film, an amorphous silicon film, a doped amorphous silicon film, and a metal film on the transparent dielectric substrate on which the gate electrode and the gate bus line are formed and etching the metal film, the amorphous silicon film, and the doped amorphous silicon film, and forming a pixel electrode by forming a protective film and a transparent metal film on the transparent dielectric substrate upon which the source/drain electrodes are formed and finely etching the transparent metal film through a lift-off process using a stripper solution.

Abstract: A method of forming a patterned material layer, the method comprising: a resist layer forming step of forming a resist layer on a substrate, the resist layer including a first photosensitive resin layer, an intermediate resin layer, and a second photosensitive resin layer; an exposing step; a developing step of partly removing the resist layer so as to form a trench exposing the substrate and partly removing the intermediate resin layer so as to form a groove on a side face of the trench, thereby forming a resist frame; a vacuum coating step of forming a vacuum coating layer having a material pattern part covering the exposed part of the substrate and a part to lift off covering the resist frame; and a liftoff step of removing the part to lift off in the vacuum coating layer together with the resist frame, so as to yield a patterned material layer.

Abstract: A wafer comprising a low-k dielectric layer is refurbished for reuse. Initially, a removable layer is provided on the wafer. The low-k dielectric layer is formed over the removable layer. The overlying low-k dielectric layer is removed from the wafer by etching away the removable layer by at least partially immersing the wafer in an etching solution. Thereafter, another low-k dielectric layer can be formed over another removable layer.

Abstract: A method of forming a gate line and gate electrode and a method of manufacturing a TFT array substrate. The metal gate line and gate electrode can be formed by: providing a substrate, forming a photoresist layer on the substrate, a photoresist pattern being formed complementary with that of the gate line and gate electrode, forming a metal Cu thin film or a composite thin film comprising a metal Cu thin film on the substrate, and removing the photoresist pattern and the metal Cu thin film or composite thin film comprising the metal Cu thin film formed thereon from the substrate.

Abstract: A method of manufacturing a redistribution circuit structure is provided. First, a substrate is provided. The substrate has a plurality of pads and a passivation layer. The passivation layer has a plurality of first openings exposing a portion of each of the pads, respectively. A first patterned photoresist layer is formed on the passivation layer. The first patterned photoresist layer has a plurality of second openings exposing a portion of each of the pads. A plurality of first bumps is formed in the second openings, respectively. An under ball metal (UBM) material layer is formed over the substrate to cover the first patterned photoresist layer and the first bumps. A plurality of conductive lines is formed on the UBM material layer. The UBM material layer is patterned to form a plurality of UBM layers using the conductive lines as a mask.

Abstract: A method of fabricating a vertical thin film transistor (vertical TFT) is disclosed, wherein a shadow mask is used to fabricate the TFT device in vertical structure. First, a metal layer is formed, which serves as ribs and a gate layer. Next, a shadow mask is disposed on the gate layer. Afterwards, the shadow mask is used as a mask to form a source layer, an organic semiconductor layer and a drain layer. Thus, the process is simplified. Since no photolithography process is required, and therefore damage of the organic semiconductor layer is avoided and a vertical TFT with desired electrical characteristics may be obtained.

Abstract: A stencil and method for depositing a coupon of underfill material onto a substrate that is to receive an integrated circuit die.

Abstract: A method of forming a solder bump may involve forming a first photoresist pattern on a wafer having a pad. The first photoresist pattern may have an opening that exposes a portion of the pad. A first under bump metallurgy (UBM) layer may be formed on the pad, and a second UBM layer may be formed on the first photoresist pattern. A second photoresist pattern may be formed that exposes the first UBM layer. A solder bump may be formed in the opening. The second photoresist pattern and the first photoresist pattern may be removed using a stripper, thereby removing the second UBM layer by a lift-off method.

Abstract: Disclosed is a method for manufacturing an array substrate utilizing a laser ablation process. With the laser ablation process, a photoresist layer is removed along with the transparent conductive layer therefrom, while maintaining other portions of the transparent conductive layer. Moreover, the laser ablation process of the invention does not need additional photo-mask, so the fabrication cost can be reduced.

Abstract: A method and an apparatus of fabricating a liquid crystal display device adapted to improve a lift-off efficiency are disclosed. The liquid crystal display device is also disclosed. The method includes forming a first thin film on a substrate; forming a photo-resist pattern on the first thin film; etching the first thin film using the photo-resist pattern as a mask; forming a second thin film on the substrate having the photo-resist pattern; forming a plurality of stripper infiltration paths; and removing the photo-resist pattern and the second thin film using a stripper within the stripper infiltration paths. The device includes two substrates facing each other; a liquid crystal layer; data lines and gate lines that cross each other to define pixel regions; thin film transistors; pixel electrodes connected to the thin film transistors; and an inorganic layer in each pixel region, wherein the inorganic layer includes a plurality of cracks.

Abstract: A dual-gate device is formed over and insulated from a semiconductor substrate which may include additional functional circuits that can be interconnected to the dual-gate device. The dual-gate device includes two semiconductor devices formed on opposite surfaces of a common active semiconductor region which is provided a thickness and material sufficient to isolate the semiconductor devices from electrostatically interacting. In one embodiment, one of the semiconductor devices includes a charge storing layer, such as an ONO layer. Such a dual-gate device is suitable for use in a non-volatile memory array.

Abstract: A method of manufacturing a field emission device (FED) using a photoresist for performing multi-patterning processes, whereby different structures can be multi-patterned using a single photoresist mask. The photoresist has a solubility to a solvent by post-exposure heat-treatment, and a complicated structure can be formed using the photoresist.

Abstract: A method of patterning a transparent conductive film adaptive for selectively etching a transparent conductive film without any mask processes, a thin film transistor for a display device using the same and a fabricating method thereof are disclosed. In the method of patterning the transparent conductive film, an inorganic material substrate is prepared. An organic material pattern is formed at a desired area of the inorganic material substrate. A thin film having a different crystallization rate depending upon said inorganic material and said organic material is formed. The thin film is selectively etched in accordance with said crystallization rate.

Abstract: A method of fabricating a liquid crystal display device includes forming a gate electrode, a gate bus line, and a gate pad on a substrate using a first mask process, forming a gate insulating layer and an active layer on an entire surface of the substrate, forming a first organic material film on an entire surface of the substrate, removing a portion of the first organic material film to expose a first portion of the gate pad, depositing a transparent film on an entire surface of the substrate, patterning the transparent film using a second half-tone mask to form a data bus line, a source electrode, a drain electrode, a pixel electrode, a channel layer, and an ohmic contact layer, exposing portions of the data pad and data bus line using a third mask, forming a second organic material film on an entire surface of the substrate, depositing a low resistance material on the data bus line, coating a passivation film on the substrate, removing the second organic material film using a lift-off process to expose a s

Abstract: Each pin fixing portion is fitted in a through-hole formed in a lifter arm, and includes a flange portion, a movable portion, a screw portion, and a pin insertion hole. A pin is fixedly screwed into the pin insertion hole at a lower end. The movable portion is inserted with an allowance in the through-hole, and the flange portion is set in contact with an upper surface of the lifter arm. The screw portion projects downward from the through-hole. A lower support portion is screwed on the screw portion and set in contact with a lower surface of the lifter arm.

Abstract: A thin film transistor substrate and a fabricating method thereof for simplifying a process are disclosed. In a liquid crystal display device according to the present invention, a gate line is provided on a substrate. A data line crosses the gate line with having a gate insulating film therebetween to define a pixel area. A thin film transistor includes a gate electrode connected to the gate line, a source electrode connected to the data line, a drain electrode opposed to the source electrode and a semiconductor layer for defining a channel between the source electrode and the drain electrode. A pixel electrode is connected to the drain electrode and is provided at said pixel area. Herein, said data line, said source electrode and said drain electrode have a double-layer structure in which a source/drain metal pattern and a transparent conductive pattern are built. Said pixel electrode is formed by an extension of the transparent conductive pattern of the drain electrode.

Abstract: A method of forming a solder bump may involve forming a first photoresist pattern on a wafer having a pad. The first photoresist pattern may have an opening that exposes a portion of the pad. A first under bump metallurgy (UBM) layer may be formed on the pad, and a second UBM layer may be formed on the first photoresist pattern. A second photoresist pattern may be formed that exposes the first UBM layer and covers the second UBM layer. A solder bump may be formed in the opening. The second photoresist pattern and the first photoresist pattern may be removed using a stripper, thereby removing the second UBM layer by a lift-off method.

Abstract: A stencil and method for depositing a coupon of underfill material onto a substrate that is to receive an integrated circuit die.

Abstract: A method of manufacturing a thin film transistor capable of simplifying a substrate structure and a manufacturing process is disclosed. The method of manufacturing a thin film transistor array substrate includes involves a three-round mask process, which includes: forming a gate pattern on a substrate; forming a gate insulating film on the substrate having the gate pattern thereon; forming a source/drain pattern and a semiconductor pattern; forming a passivation film to protect the thin film transistor on an entire surface of the substrate; forming a photo-resist pattern on the passivation film; patterning the passivation film using the photo-resist pattern to form a passivation film pattern; and forming a transparent electrode pattern being extended from a lateral surface of the passivation film pattern and formed at an area except for the passivation film pattern.

Abstract: According to an embodiment of the present invention, a method of producing an electronic circuit comprises printing first metal-containing resin particles which consist of at least a thermosetting resin and fine metal particles and second metal-containing resin particles which consist of at least a thermoplastic resin and fine metal particles by electrophotography to form a first base pattern which consists of the first metal-containing resin particles and a second base pattern which consists of the second metal-containing resin particles on a substrate; forming a first metal conductor layer on the first and second base patterns; forming a second metal conductor layer on the first metal conductor layer by electrolytic plating by supplying electric current to the first metal conductor layer; and removing the second base pattern and the first and second metal conductor layers which are formed on the second base pattern.

Abstract: The invention includes methods of forming patterns in low-k dielectric materials by contact lithography. In a particular application, a mold having a first pattern is pressed into a low-k dielectric material to form a second pattern within the material. The second pattern is substantially complementary to the first pattern. The mold is then removed from the low-k dielectric material. The invention also includes a method of forming a mold; and includes a mold configured to pattern a mass over a semiconductor substrate during contact lithography of the mass.

Abstract: A wafer-scale fabrication approach for manufacturing single-walled carbon nanotube (SWNT) tips is implemented. Catalyst material is selectively placed (e.g., patterned) onto a plurality of prefabricated elevated structures (e.g., silicon tips) on a wafer. SWNTs are grown protruding from the catalyst on the elevated structures. The resulting SWNT protruding from a tip can be implemented in a variety of applications, such as in atomic force microscopy (AFM). With this approach, nanotube tips can be implemented for a variety of applications, including advanced nanoscale imaging, imaging of solid-state and soft biological systems and for scanning probe lithography.

Abstract: A method for fabricating at least one mesa or ridge structure in a layer or layer sequence, in which a sacrificial layer (4) is applied and patterned above the layer or layer sequence. A mask layer is applied and patterned above the sacrificial layer for definition of the mesa or ridge dimensions. The sacrificial layer (4) and of the layer or layer sequence are removed so that the mesa or ridge structure is formed in the layer or layer sequence. A part of the sacrificial layer (4) is selectively removed from the side areas thereof which have been uncovered in the previous step, so that a sacrificial layer remains which is narrower in comparison with a layer that has remained above the sacrificial layer as seen from the layer or layer sequence. A coating is applied at least to the sidewalls of the structure produced in the previous steps so that the side areas of the residual sacrificial layer are not completely overformed by the coating material.

Abstract: An aspect of the present invention is a method of forming a contact in a thin-film device. The method includes forming a liftoff stencil, depositing at least one material through the liftoff stencil, removing a portion of the liftoff stencil, forming a re-entrant profile with the remaining portion of the liftoff stencil and depositing a conductor material in contact with the at least one material on the re-entrant profile.

Abstract: A process that advantageously forms MRAM cells without the application of ion beam milling processes. Unlike conventional processes that rely on ion beam milling processes to remove materials from a magnetoresistive sandwich from areas other than areas that will later form MRAM cell bodies, this process forms a layer of photoresist over areas other than those areas that correspond to MRAM cell bodies. The photoresist is lifted off after the deposition of a magnetoresistive sandwich that forms the MRAM cell bodies, thereby safely removing the magnetoresistive sandwich from undesired areas while maintaining the magnetoresistive sandwich in the areas corresponding to MRAM cell bodies.

Abstract: Magnetic tunnel junction devices can be fabricated using a two-step deposition process wherein respective portions of the magnetic tunnel junction stack are defined independently of one another.

Abstract: A method of fabricating a vertically profiled electrode like a T-gate 40 on a semiconductor substrate 20 is described. The method comprises providing a resist structure 34 on the substrate 20, the resist structure 34 containing at least a first resist pattern 24? arranged on the substrate 20 and having a first opening 26, the first resist being negative resist, and a second resist pattern 32 having a second opening 30 surrounding the first opening 26. The vertical profile of the gate electrode 40 is defined by the contours and the relative location of the first and the second opening 26, 30. On the resist structure 34 a metal 38 is deposited and lift-off is performed to remove the second resist 32 together with the metal 38 deposited thereon.

Abstract: A method for forming a conductive layer is disclosed, which has the following steps. First, a substrate is provided, and then a patterned photoresist layer having an undercut is formed on the substrate. After that, at least one conductive layer is deposited on the substrate. Finally, the patterned photoresist layer is lifted off; wherein the shape of the conductive layer remaining on the substrate is complementary to that of the patterned photoresist layer.

Abstract: A method of forming a gate structure includes forming sequentially a pad layer and a first photoresist layer over a substrate. A cross-linked surface layer is formed on the surface of the first photoresist layer, followed by rounding the profile of the first photoresist layer, and removing the exposed pad layer to expose the substrate. A second photoresist layer is formed over the first photoresist layer, wherein a portion of the first photoresist layer and the exposed substrate are exposed by the second photoresist layer. Thereafter, a conductive layer is formed, wherein the conductive layer formed on the second photoresist layer is separated from the conductive layer formed on the first photoresist layer and the exposed substrate. The first and the second photoresist layers are removed while the conductive layer on the second photoresist layer is concurrently being striped. The remaining conductive layer serves as a gate structure.

Abstract: A semiconductor manufacturing method that includes defining a substrate, depositing a polysilicon layer over the substrate, depositing a layer of photoresist over the polysilicon layer, patterning and defining the photoresist layer, depositing a layer of inorganic material over the patterned and defined photoresist layer, wherein the layer of inorganic material is conformal and photo-insensitive, and anisotropic etching the layer of inorganic material and the layer of semiconductor material.

Abstract: An improved and novel method of forming a tiered structure, such as a T-gate structure, including the fabrication of a stabilized resist layer that provides for the prevention of interlayer intermixing with the deposition of subsequent resist layers. The method includes patterning a base resist layer to provide for an opening which will form the stem of the tiered structure and subsequently stabilizing the resist base layer without deforming the stem opening. Next, a resist stack is deposited on an uppermost surface of the stabilized resist layer. Patterning the resist stack provides for an opening on an uppermost layer or portion, and a reentrant profile in a portion of the resist stack adjacent the stabilized resist layer. Metallization and subsequent removal of the resist layers results in a tiered structure, such as a T-gate structure, formed using only low to medium molecular weight, linear polymeric materials such as those used in positive optical resists in optical lithography.

Abstract: A method of forming a poly-poly capacitor, a MOS transistor, and a bipolar transistor simultaneously on a substrate comprising the steps of depositing and patterning a first layer of polysilicon on the substrate to form a first plate electrode of said capacitor and on an electrode of the MOS transistor, and depositing and patterning a second layer of polysilicon on the substrate to form a second plate electrode of said capacitor and an electrode of the bipolar transistor.