Abstract: A method of forming circuitry components includes forming a stack of horizontally extending and vertically overlapping features. The stack has a primary portion and an end portion. At least some of the features extend farther in the horizontal direction in the end portion moving deeper into the stack in the end portion. Operative structures are formed vertically through the features in the primary portion and dummy structures are formed vertically through the features in the end portion. Horizontally elongated openings are formed through the features to form horizontally elongated and vertically overlapping lines from material of the features. The lines individually extend from the primary portion into the end portion, and individually laterally about sides of vertically extending portions of both the operative structures and the dummy structures.

Abstract: A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material.

Abstract: Resistance variable memory cells having a plurality of resistance variable materials and methods of operating and forming the same are described herein. As an example, a resistance variable memory cell can include a plurality of resistance variable materials located between a plug material and an electrode material. The resistance variable memory cell also includes a first conductive material that contacts the plug material and each of the plurality of resistance variable materials and a second conductive material that contacts the electrode material and each of the plurality of resistance variable materials.

Abstract: Multiple threshold voltage (Vt) field-effect transistor (FET) devices and techniques for the fabrication thereof are provided. In one aspect, a FET device is provided including a source region; a drain region; at least one channel interconnecting the source and drain regions; and a gate, surrounding at least a portion of the channel, configured to have multiple threshold voltages due to the selective placement of at least one band edge metal throughout the gate.

Abstract: Embodiments of the invention provide dual workfunction semiconductor devices and methods for manufacturing thereof. According to one embodiment, the method includes providing a substrate containing first and second device regions, depositing a dielectric film on the substrate, and forming a first metal-containing gate electrode film on the dielectric film, wherein a thickness of the first metal-containing gate electrode film is less over the first device region than over the second device region. The method further includes depositing a second metal-containing gate electrode film on the first metal-containing gate electrode film, patterning the second metal-containing gate electrode film, the first metal-containing gate electrode film, and the dielectric film to form a first gate stack above the first device region and a second gate stack above the second device region.

Abstract: A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material.

Abstract: A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material.

Abstract: A vertical pillar semiconductor device may include a substrate, a group of channel patterns, a gate insulation layer pattern and a gate electrode. The substrate may be divided into an active region and an isolation layer. A first impurity region may be formed in the substrate corresponding to the active region. The group of channel patterns may protrude from a surface of the active region and may be arranged parallel to each other. A second impurity region may be formed on an upper portion of the group of channel patterns. The gate insulation layer pattern may be formed on the substrate and a sidewall of the group of channel patterns. The gate insulation layer pattern may be spaced apart from an upper face of the group of channel patterns. The gate electrode may contact the gate insulation layer and may enclose a sidewall of the group of channel patterns.

Abstract: An object is to provide a display device which operates stably with use of a transistor having stable electric characteristics. In manufacture of a display device using transistors in which an oxide semiconductor layer is used for a channel formation region, a gate electrode is further provided over at least a transistor which is applied to a driver circuit. In manufacture of a transistor in which an oxide semiconductor layer is used for a channel formation region, the oxide semiconductor layer is subjected to heat treatment so as to be dehydrated or dehydrogenated; thus, impurities such as moisture existing in an interface between the oxide semiconductor layer and the gate insulating layer provided below and in contact with the oxide semiconductor layer and an interface between the oxide semiconductor layer and a protective insulating layer provided on and in contact with the oxide semiconductor layer can be reduced.

Abstract: Disclosed is a method of fabricating a semiconductor device that includes both an enhancement-mode FET and a depletion-mode FET. The method includes forming an opening in a gate electrode for the depletion-mode FET. The opening is located in or in the vicinity of one of the overlapping regions in which the gate electrode extends over active regions. The method further includes ion-implanting dopant impurities into the active regions at an oblique angle using the gate electrode as a mask, thereby to form the doped region that is located under the opening and continuously extending from one of the opposite sides of the gate electrode to the other.

Abstract: Multiple threshold voltage (Vt) field-effect transistor (FET) devices and techniques for the fabrication thereof are provided. In one aspect, a FET device is provided including a source region; a drain region; at least one channel interconnecting the source and drain regions; and a gate, surrounding at least a portion of the channel, configured to have multiple threshold voltages due to the selective placement of at least one band edge metal throughout the gate.

Abstract: In a transistor region, a source interconnect layer and a gate electrode are buried in trenches. A source extending region is provided adjacent to the transistor region or in the transistor region, and a source interconnect layer is designed to protrude from the upper end of a trench. This source interconnect layer is connected to a source electrode formed in the transistor region immediately above the trench. A gate extending region is provided outside the source extending region, and the gate electrode and a gate interconnect layer are connected. The gate electrode is formed by performing etchback without forming a resist pattern, after a polysilicon film is formed. Here, the polysilicon film remains like a side-wall on the sidewall of the portion of the source interconnect layer protruding from the upper end of the trench.

Abstract: A vertical pillar semiconductor device may include a substrate, a group of channel patterns, a gate insulation layer pattern and a gate electrode. The substrate may be divided into an active region and an isolation layer. A first impurity region may be formed in the substrate corresponding to the active region. The group of channel patterns may protrude from a surface of the active region and may be arranged parallel to each other. A second impurity region may be formed on an upper portion of the group of channel patterns. The gate insulation layer pattern may be formed on the substrate and a sidewall of the group of channel patterns. The gate insulation layer pattern may be spaced apart from an upper face of the group of channel patterns. The gate electrode may contact the gate insulation layer and may enclose a sidewall of the group of channel patterns.

Abstract: Disclosed is a method of fabricating a semiconductor device that includes both an enhancement-mode FET and a depletion-mode FET. The method includes forming an opening in a gate electrode for the depletion-mode FET. The opening is located in or in the vicinity of one of the overlapping regions in which the gate electrode extends over active regions. The method further includes ion-implanting dopant impurities into the active regions at an oblique angle using the gate electrode as a mask, thereby to form the doped region that is located under the opening and continuously extending from one of the opposite sides of the gate electrode to the other.

Abstract: A semiconductor structure and a method of forming the same. The semiconductor structure includes a semiconductor substrate, a gate dielectric layer on top of the semiconductor substrate. The structure also includes a first metal containing region on top of the gate dielectric layer. The structure also includes a second metal containing region on top of the gate dielectric layer wherein the first and second metal containing regions are in direct physical contact with each other. The structure further includes a gate electrode layer on top of both the first and second metal containing regions and the gate electrode layer is in direct physical contact with both the first and second metal containing regions. The structure further includes a patterned photoresist layer on top of the gate electrode layer.

Abstract: A method of forming an integrated circuit structure on a substrate, the substrate includes a primary region and a secondary region. A first layer of a first material of a first thickness is formed over the substrate. A portion of the first layer is removed over the primary region to expose the substrate. The structure is exposed to an oxidizing medium. This forms a second layer, for example, of an oxide material primary region of the substrate. The second layer has a second thickness. Additionally, at least a portion of said first layer is converted to a third layer, for example, of an oxynitride material. The third layer has a third thickness.

Abstract: A transistor suitable for high-voltage applications and a method of manufacture is provided. A first device is formed by depositing a dielectric layer and a conductive layer over a substrate. A hard mask is deposited over the conductive layer and patterned using photolithography techniques. The photoresist material is removed prior to etching the underlying conductive layer and dielectric layer. The hard mask is also used as an implant mask. Another mask may be deposited and formed over the conductive layer to form other devices in other regions of the substrate. The other mask is preferably removed from over the hard mask prior to etching the conductive layer and the dielectric layer.

Abstract: A method of fabricating a double gate FET on a silicon substrate includes the steps of sequentially epitaxially growing a lower gate layer of crystalline rare earth silicide material on the substrate, a lower gate insulating layer of crystalline rare earth insulating material, an active layer of crystalline semiconductor material, an upper gate insulating layer of crystalline rare earth insulating material, and an upper gate layer of crystalline rare earth conductive material. The upper gate layer and the upper gate electrically insulating layer are etched and a contact is deposited on the upper gate layer to define an upper gate structure. An impurity is implanted into the lower gate layer to define a lower gate area aligned with the upper gate structure. A source and drain are formed in the active layer and contacts are deposited on the source and drain, respectively.

Abstract: Multiple threshold voltage (Vt) field-effect transistor (FET) devices and techniques for the fabrication thereof are provided. In one aspect, a FET device is provided including a source region; a drain region; at least one channel interconnecting the source and drain regions; and a gate, surrounding at least a portion of the channel, configured to have multiple threshold voltages due to the selective placement of at least one band edge metal throughout the gate.

Abstract: A method for fabricating a semiconductor device includes etching a substrate to form a first recess having a micro trench, etching the substrate disposed under the first recess to form a second recess having a profile substantially vertical and a width greater than a portion of the first recess where no micro trench is formed, etching the substrate disposed under the second recess to form a third recess having a profile substantially spherical, and forming a gate pattern over a resultant recess including the first to third recesses.

Abstract: Methods for fabricating stressed MOS devices are provided. In one embodiment, the method comprises providing a silicon substrate having a P-well region and depositing a polycrystalline silicon gate electrode layer overlying the P-well region. P-type dopant ions are implanted into the polycrystalline silicon gate electrode layer to form a P-type implanted region and a first polycrystalline silicon gate electrode is formed overlying the P-well region. Recesses are etched into the P-well region using the first polycrystalline silicon gate electrode as an etch mask. The step of etching is performed by exposing the silicon substrate to tetramethylammonium hydroxide. A tensile stress-inducing material is formed within the recesses.

Abstract: A semiconductor circuit has a plurality of MISFETs formed with channel films comprised of semiconductor layers on an insulation film. Channel film thicknesses of each MISFET are different. A correlation relationship is fulfilled where concentration per unit area of impurity contained in the channel films becomes larger for MISFETs of a thicker channel film thickness. As a result, it is possible to suppress deviation of threshold voltage caused by changes in channel film thickness. In this event, designed values for the channel film thicknesses of the plurality of MISFETs are preferably the same, and the difference in channel film thickness of each MISFET may depend on statistical variation from the designed values. The concentration of the impurity per unit area is proportional to the channel film thickness, or is a function that is convex downwards with respect to the channel film thickness.

Abstract: A manufacturing method for an integrated semiconductor structure and a corresponding semiconductor structure is disclosed. The method includes forming a peripheral circuitry in a peripheral device region, wherein the peripheral circuitry includes a peripheral transistor at least partially formed in the semiconductor substrate and having a first gate dielectric formed in a first high temperature process step. The method further includes forming a plurality of memory cells in a memory cell region, each of said memory cells including an access transistor at least partially formed in a semiconductor substrate and having a second gate dielectric formed in a second high temperature process step and having a metallic gate conductor. The first and second high temperature process steps are performed before a step of forming the metallic gate conductor.

Abstract: A method for fabricating a semiconductor device includes etching a predetermined portion of a substrate to form a first recess having a bottom middle portion roundly projected and bottom edge portions tapered to have a micro-trench profile; and etching the substrate beneath the first recess to form a second recess, the second recess being rounded and being wider than the first recess.

Abstract: Embodiments disclosed herein include methods in which a pair of openings are formed into semiconductor material, with the openings being spaced from one another by a segment of the semiconductor material. Liners are formed along sidewalls of the openings, and then semiconductor material is isotropically etched from bottoms of the openings to merge the openings and thereby completely undercut the segment of semiconductor material. Embodiments disclosed herein may be utilized in forming SOI constructions, and in forming field effect transistors having transistor gates entirely surrounding channel regions. Embodiments disclosed herein also include semiconductor constructions having transistor gates surrounding channel regions, as well as constructions in which insulative material entirely separates an upper semiconductor material from a lower semiconductor material.

Abstract: A fabrication method for a semiconductor device includes a step of forming a gate insulating film on a semiconductor layer, and a step of forming a first gate electrode layer on the gate insulating film. The fabrication method also includes a step of forming a pocket ion region under the first gate electrode layer, and a step of forming a second gate electrode layer overlaying the first gate electrode layer after forming the pocket ion region.

Abstract: Various embodiments are directed to different methods and systems relating to design and implementation of memory cells such as, for example, static random access memory (SRAM) cells. In one embodiment, a memory cell may include a first layer of conductive material and a second layer of conductive material. The first layer may include a first gate region and a first interconnect region, and the second layer of conductive material may include a second gate region and a second interconnect region. It will be appreciated that the various techniques described herein for using multiple layers of conductive material to form interconnect regions and/or gate regions of memory cells provides extra degrees of freedom in fine tuning memory cell parameters such as, for example, oxide thickness, threshold voltage, maximum allowed gate voltage, etc.

Abstract: A semiconductor device that has a common border between P and N wells is susceptible to photovoltaic current that is believed to be primarily generated from photons that strike this common border. Photons that strike the border are believed to create electron/hole pairs that separate when created at the PN junction of the border. The photovoltaic current can have a sufficient current density to be destructive to the metal connections to a well if the area of these metal connections to the well is small relative to the length of the border. This photovoltaic current can be reduced below destructive levels by covering the common border sufficiently to reduce the number of photons hitting the common border. The surface area of the connections can also be increased to alleviate the problem.

Abstract: A method for fabricating a semiconductor memory device is described. An insulating layer is disposed on a semiconductor substrate. A matrix of semiconductor memory elements is disposed in the substrate. The semiconductor memory elements include a plurality of contact holes formed in the insulating layer. One contact hole is formed in the insulating layer for each of the semiconductor memory elements. A bit definition region is disposed in the semiconductor substrate underneath each of the contact holes. A contact plug is disposed in each of the contact holes and is in electrical contact with the bit definition region. The bit definition region is configured such that a contact resistance between the semiconductor substrate and the contact plug defines a bit to be stored in the semiconductor memory elements, An evaluation circuit is connected to and evaluates the contact resistance of the semiconductor memory elements.

Abstract: Various techniques are described which utilize multiple poly-silicon layers in the design and fabrication of various logic elements that are used in semiconductor devices. According to a specific implementation of the present invention, logic gate cell sizes and memory array cell sizes may be reduced by fabricating various transistor gates using multiple poly-silicon layers. The techniques of the present invention of using multiple layers of poly-silicon to form transistor gates of logic elements provides extra degrees of freedom in fine tuning transistor parameters such as, for example, oxide thickness, threshold voltage, maximum allowed gate voltage, etc.

Abstract: A method of preparing a ring-formed body comprises the steps of: forming, on a substrate, a column in a columnar form which serves as a core of a ring-formed body; depositing, on both the substrate and the column, a ring-formed body forming film for forming the ring-formed body so that the ring-formed body forming film formed on the substrate and that formed on the column are separated from each other; forming a mask film for covering the ring-formed body forming film; and subjecting the mask film and ring-formed body forming film to anisotropic dry etching so that the films remain on a sidewall of the column, forming a ring-formed body comprised of the ring-formed body forming film having the mask film.

Abstract: A method of manufacturing mask ROM is provided. A buried bit line is formed in a substrate and then a gate and a word line are formed over the substrate. Thereafter, a pre-coding layer with a plurality of pre-coding openings therein is formed over the substrate in a relatively high precision process. The pre-coding openings correspond in position to a plurality of coding regions on the substrate underneath the gate. A filler material is deposited into the pre-coding openings to form a filler layer. A coding mask having a plurality of coding openings is formed over the substrate in a relatively low precision process. The filler material inside the pre-coding openings that correspond in position to the code openings in the coding mask is removed. The coding mask is removed. Finally, a coding ion implant is carried out using the pre-coding layer and the filler layer as mask and hence ions are implanted into the code region through the pre-coding openings.

Abstract: A mask ROM device is described. The mask ROM device includes a substrate, a gate, a double diffused source/drain region that comprises a first doped region and a second doped region, a channel region, a coding region, a dielectric layer and a word line. The gate is disposed on the substrate. The double diffused source/drain region is positioned beside the sides of the gate in the substrate, wherein the second doped region is located at the periphery of the first doped region in the substrate. The channel region is located between the double diffused source/drain region in the substrate. The coding region is disposed in the substrate at the intersection between the sides of the channel region and the double diffused source/drain region. The dielectric layer is disposed above the double diffused source/drain region, while the word line is disposed above the dielectric layer and the gate.

Abstract: Various techniques are described which utilize multiple poly-silicon layers in the design and fabrication of various logic elements that are used in semiconductor devices. According to a specific implementation of the present invention, logic gate cell sizes and memory array cell sizes may be reduced by fabricating various transistor gates using multiple poly-silicon layers. The techniques of the present invention of using multiple layers of poly-silicon to form transistor gates of logic elements provides extra degrees of freedom in fine tuning transistor parameters such as, for example, oxide thickness, threshold voltage, maximum allowed gate voltage, etc.

Abstract: A method of fabricating a mask read only memory. Embedded bit line are formed in a substrate. A gate dielectric layer and a word line are formed on the substrate. The word line is perpendicular to the bit lines. The substrate under the word line and between each pair of the bit lines is referred as a memory unit. A first dielectric layer is formed to cover the substrate. A plurality of coding windows is formed in the first dielectric layer over the memory units. Ions are implanted into the memory cells exposed by the coding windows, and a second dielectric layer is formed to fill the coding windows.

Abstract: Examples including non-volatile semiconductor memory devices in which digitized image data and voice data can be more efficiently written and read, and methods for manufacturing the same, are described. In one example, a non-volatile semiconductor memory device 300 may include a first memory element 100 and a second memory element 200 formed in a wafer 11 and mutually isolated by an element isolation region 38, a first impurity diffusion layer 16 and a second impurity diffusion layer 14. The first and second memory elements 100 and 200 include gate dielectric layers 20 and 120, floating gates 22 and 122, selective oxide dielectric layers 24 and 124 and third impurity diffusion layers 15 and 25, respectively, and also include a common intermediate dielectric layer 26 and a common control gate 28, and connected to the first and second impurity diffusion layers 16 and 14 that are commonly shared.

Abstract: A method for fabricating an UV-programmed P-type Mask ROM is described. The threshold voltages of all memory cells are raised at first to make each memory cell be in a first logic state, in which the channel is hard to switch on, in order to prevent a leakage current. After the bit lines and the word lines are formed, the Mask ROM is programmed by irradiating the substrate with UV light to inject electrons into the ONO layer under the openings to make the memory cells under the openings be in a second logic state.

Abstract: A method for manufacturing a semiconductor memory device is disclosed. A spacer of a material having a high etching selection ratio with respect to an interdielectric layer is formed on a sidewall of a gate electrode. A refractory metal silicide layer is formed on an upper surface of the gate electrode and on an upper surface of a substrate on which source and drain regions are formed, thereby providing a contact hole self-aligned between the gate electrodes. Also, an ion implantation process is performed on the entire active region after the contact hole is filled with metal such as tungsten, and an impurity region is formed only on a lower portion of the gate electrode.

Abstract: The present invention provides a double gated transistor and a method for forming the same that results in improved device performance and density. The preferred embodiment of the present invention provides a double gated transistor with asymmetric gate doping, where one of the double gates is doped degenerately n-type and the other degenerately p-type. By doping one of the gates n-type, and the other p-type, the threshold voltage of the resulting device is improved. Additionally, the preferred transistor design uses an asymmetric structure that results in reduced gate-to-drain and gate-to-source capacitance. In particular, dimensions of the weak gate, the gate that has a workfunction less attractive to the channel carriers, are reduced such that the weak gate does not overlap the source/drain regions of the transistor. In contrast the strong gate, the gate having a workfunction that causes the inversion layer to form adjacent to it, is formed to slightly overlap the source/drain regions.

Abstract: In an LDMOS, an n-type region 6, which is formed to have a concentration higher than that of an n-type substrate 1 and whose concentration gradually increases from the n-type substrate 1 to an n+ type drain region 5, is disposed so as to surround the n+-type drain region 5. Further, a p+-type contact region 9 disposed adjacent to an n+-type source region 8 is formed so as to extend below the n+-type source region 8 so that a parasitic transistor formed by the n+-type source region 8, a p-type base region 7 and the n-type substrate 1 is hardly turned ON.

Abstract: The method of manufacturing a semiconductor device comprises the steps of: forming a gate electrode on a semiconductor substrate through a gate insulated film; forming source/drain regions to be adjacent to the gate electrode forming an Al wiring through an interlayer insulating film covering the gate electrode; and implanting impurity ions into a surface of the semiconductor substrate using as a mask the Al wiring and a photoresist formed thereon, thereby writing information into each of elements constituting a mask ROM and changing an outputting manner at an output port.

Abstract: A method of fabricating a mask read only memory. Gate stacked structures, each of which made up of a gate dielectric layer, a gate conductive layer and a gate cap layer, are formed on a substrate. Source/drain regions are between, but not adjacent to the gate stacked structures. Regions between the source/drain regions and the gate stacked structures are coding areas. A dielectric layer is formed to fill spaces between the gate stacked structures. A photoresist layer with openings exposing the first dielectric layer on the coding areas is formed. The exposed first dielectric layer is removed to form implantation openings of the coding areas. Ion implantation is performed on the exposed coding areas. The photoresist layer is removed, and another dielectric layer is formed to fill the implantation openings. An etching back process is performed to expose the gate conductive layer. A word line is formed on the gate conductive layer.

Abstract: A method of manufacturing a mask ROM. A sacrificial silicon oxide layer is formed on the active region upon the substrate. Patterning the sacrificial silicon oxide layer in order to form a plurality of parallel openings, thereby exposing a portion of the active region. A polysilicon layer is formed on the openings and openings are formed thereon. An ion implantation process is performed on the polysilicon layer. Using a thermal flow process, the ions within the polysilicon layer are driven through the openings into the lower portion of the substrate, thereby forming an ion doping region. The polysilicon layer is etchbacked until the sacrificial silicon oxide layer is exposed. The sacrificial silicon oxide layer is removed.

Abstract: The manufacture of a trench-gate semiconductor device, for example a power transistor or a memory device includes the steps of forming at a surface (10a) of a semiconductor body (10) a first mask (51) having a first window (51a), providing a thin layer of a second material (52) in the first window (51a), forming an intermediate mask (53A, 53B) of a third material having curved sidewalls and using the intermediate mask (53A, 53B) to form two L-shaped parts (52A, 52D and 52B, 52E) of the second material with a second window (52a) which is used to etch a trench-gate trench (20). The rectangular base portion (52D, 52E) of each L-shaped part ensures that the trench (20) is maintained narrow during etching. Narrow trenches are advantageous for low specific on-resistance and low RC delay in low voltage cellular trench-gate power transistors.

Abstract: A novel transistor with a low resistance ultra shallow tip region and its method of fabrication. The novel transistor of the present invention has a source/drain extension or tip comprising an ultra shallow region which extends beneath the gate electrode and a raised region.

Abstract: A drive transistor for an ink jet print head includes a semiconductor substrate having a serpentine channel of a first type doping, the channel comprising substantially parallel first and second serpentine channel portions, the first and second serpentine channel portions defining an inner region disposed between the first and second serpentine channel portions and an outer region disposed outside the first and second serpentine channel portions. A drain of a second type doping which is disposed within the inner region. A source of a second type doping which is disposed within the outer region. The transistor has a serpentine gate that overlies the serpentine channel. An elongate drain conductor, which tapers from a wide drain conductor end to a narrow drain conductor end, at least partially overlies a portion of the drain and the serpentine channel. An elongate source conductor has two tapered source conductor portions that at least partially overly the source and the serpentine channel.

Abstract: An ESD protection structure that when connected between an input/output pad on a semiconductor substrate and a reference voltage source, will protect internal circuits formed on the semiconductor substrate from over stress due to excessively high voltages of an ESD voltage source. The ESD protection structure has a uniform discharge current to prevent damage to the ESD protection device thus allowing increased protection to the internal circuits. The ESD protection device has at least one source region that is the emitters of parasitic transistors connected to the reference voltage source and at least one drain region that is the collectors of the parasitic transistors connected to the junction of the input/output pad and the internal circuitry. The ESD protection device further has at least one gate electrode formed above a channel region. The channel region is the region is between each of the source regions and the drain regions. The gate electrodes are connected to the reference voltage source.

Abstract: A method for forming a semiconductor device. A substrate is provided. A first electrically insulating layer is formed on the substrate. A second electrically insulating layer is formed on the first electrically insulating layer. Openings are formed through the second electrically insulating layer down to the level of the first electrically insulating layer. Spacers are formed on opposing sidewalls of the openings. The spacers on one of the opposing side walls of the openings are removed, thereby exposing portions of the first electrically insulating layer. Exposed portions of the first electrically insulating layer in the openings are removed, thereby exposing portions of the substrate. The spacers on another of the opposing sidewalls of the openings are removed, thereby exposing portions of the first electrically insulating layer. A third electrically insulating layer is formed in the openings over the exposed portions of the first electrically insulating layer and the exposed portions of the substrate.

Abstract: A method of fabricating a mask read-only memory. Before carrying out a code implantation, a coding mask is used as an etching mask to remove a portion of the inter-metal dielectric layer and the inter-layer dielectric layer above the coding positions, thereby forming a contact window. The code implantation is subsequently carried out so these ions can easily reach the coding positions via the contact opening.

Abstract: A memory device and a method of manufacturing the same in accordance with the present invention has an improved writing and erasing efficiency and an improved reliability. The memory device includes a first conductivity type substrate having second conductivity type source and drain regions spaced apart from each other. A source electrode having a T-shaped rail structure is formed in contact with the source region, and a drain electrode having a T-shaped rail structure is formed in contact with the drain region. An I-shaped floating gate is formed on the substrate between the source electrode and the drain electrode with a control gate formed on the floating gate.